Switching power connector and electrical connection element with safety interlock

ABSTRACT

An electrical connection element is for a power connector. The power connector includes an electrical component having a number of first electrical mating members. The electrical connection element comprises: a housing including a number of second electrical mating members structured to be electrically connected to the number of first electrical mating members; a contact assembly enclosed by the housing and being electrically connected to the number of second electrical mating members; and an operating mechanism for opening and closing the contact assembly. The contact assembly is structured to electrically connect and disconnect power while the number of first electrical mating members remain mechanically coupled to the number of second electrical mating members.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation patent application and claimspriority to U.S. patent application Ser. No. 15/331,960, filed Oct. 24,2016, which application is a continuation-in-part application and claimspriority to U.S. patent application Ser. No. 15/215,918, filed Jul. 21,2016, which application is a continuation of U.S. patent applicationSer. No. 14/800,768, filed on Jul. 16, 2015, and entitled “POWERCONNECTOR, AND ELECTRICAL CONNECTION ELEMENT AND OPERATING METHODTHEREFOR.”

BACKGROUND Field

The disclosed concept pertains generally to power connectors. Thedisclosed concept also pertains to electrical connection elements forpower connectors. The disclosed concept further pertains to methods ofoperating power connectors.

Background Information

Power connectors are used in many different electrical applications,such as, for example, in commercial applications (e.g., employed withstoves and fryers) and in shipping industries (e.g., with refrigerationequipment). Typically, power connectors include a line side receptacle,which is electrically connected to a power source, and a load sidereceptacle. The line side receptacle has a number of metallic sleeves.The load side receptacle has a number of metallic pins. In operation,the pins are inserted into the sleeves in order to provide an electricalpathway between the line side receptacle and the load side receptacle.

A substantial drawback with power connectors is known as “hot plugging,”which occurs when there is a live electrical connection or disconnectionmade between the pins and the sleeves, and the integrity of the pins andsleeves is compromised. For example, when the pins are inserted into thesleeves, electricity is permitted to flow therethrough. When thisconnection is made, a significant amount of switching energy is focusedon the pins and the sleeves, which can undesirably result in the pinsand sleeves melting, and/or being welded together, and/or damage to thesurfaces of the pins and the sleeves, and/or an arc flash (e.g., “hotplugging”).

There is, thus, room for improvement in power connectors and inelectrical connection elements therefor.

There is also room for improvement in methods of operating powerconnectors.

SUMMARY

These needs and others are met by embodiments of the disclosed concept,which are directed to a power connector, and electrical connectionelement and operating method therefor in which a contact assemblyelectrically connects and disconnects power while separate matingmembers remain mechanically coupled.

In accordance with one aspect of the disclosed concept, an electricalconnection element for a power connector is provided. The powerconnector includes an electrical component having a number of firstelectrical mating members. The electrical connection element comprises:a housing including a number of second electrical mating membersstructured to be electrically connected to the number of firstelectrical mating members; a contact assembly enclosed by the housingand being electrically connected to the number of second electricalmating members; and an operating mechanism for opening and closing thecontact assembly. The contact assembly is structured to electricallyconnect and disconnect power while the number of first electrical matingmembers remain mechanically coupled to the number of second electricalmating members.

In accordance with another aspect of the disclosed concept, a powerconnector comprises: an electrical component having a number of firstelectrical mating members; and an electrical connection elementcomprising: a housing including a number of second electrical matingmembers electrically connected to the number of first electrical matingmembers, a contact assembly enclosed by the housing and beingelectrically connected to the number of second electrical matingmembers, and an operating mechanism for opening and closing the contactassembly. The contact assembly is structured to electrically connect anddisconnect power while the number of first electrical mating membersremain mechanically coupled to the number of second electrical matingmembers.

In accordance with another aspect of the disclosed concept, a method ofoperating a power connector is provided. The power connectors comprisean electrical component and an electrical connection element. Theelectrical component has a number of first electrical mating members.The electrical connection element comprises a housing including a numberof second electrical mating members, a contact assembly enclosed by thehousing and being electrically connected to the number of secondelectrical mating members, and an operating mechanism for opening andclosing the contact assembly. The method comprises the steps of:mechanically coupling the number of first electrical mating members tothe number of second electrical mating members; closing the contactassembly in order to electrically connect power after the number offirst electrical mating members are mechanically coupled to the numberof second electrical mating members; and opening the contact assembly inorder to electrically disconnect power while the number of firstelectrical mating members are mechanically coupled to the number ofsecond electrical mating members.

BRIEF DESCRIPTION OF THE DRAWINGS

A full understanding of the disclosed concept can be gained from thefollowing description of the preferred embodiments when read inconjunction with the accompanying drawings in which:

FIG. 1 is a simplified view of a power connector and electricalconnection element therefor, in accordance with a non-limitingembodiment of the disclosed concept;

FIG. 2 is another simplified view of the power connector and electricalconnection element therefor of FIG. 1, showing the operating lever invarious positions in dashed line drawing;

FIG. 3 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 4 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 5 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 6 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 7 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 8A is a simplified view of a portion of the power connector andelectrical connection element therefor of FIG. 7, showing the operatingmechanism in a position corresponding to the contact assembly beingopen;

FIG. 8B is another simplified view of the portion of the power connectorand electrical connection element therefor of FIG. 8A, showing theoperating mechanism in a position corresponding to the contact assemblybeing closed;

FIG. 9 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 10 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 11A is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 11B is a schematic view of a portion of the electrical connectionelement of FIG. 11A, shown with portions removed in order to see hiddenstructures;

FIG. 12 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 13 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 14 is a simplified view of a portion of a power connector andelectrical connection element therefor, in accordance with anothernon-limiting embodiment of the disclosed concept;

FIG. 15 is a simplified view of a portion of a power connector andelectrical connection element therefor, in accordance with anothernon-limiting embodiment of the disclosed concept;

FIG. 16 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept;

FIG. 17 is a simplified view of a power connector and electricalconnection element therefor, showing the second mating assembly in afirst position, in accordance with another non-limiting embodiment ofthe disclosed concept;

FIG. 18 is a top plan view of the electrical connection element of FIG.17;

FIG. 19 is a simplified view of the portion of the power connector andelectrical connection element therefor of FIG. 17, showing the secondmating assembly in a third position;

FIG. 20 is a simplified view of the portion of the power connector andelectrical connection element therefor of FIG. 17, showing the secondmating assembly in a second position;

FIG. 21 is a simplified view of a portion of a power connector andelectrical connection element therefor, in accordance with anothernon-limiting embodiment of the disclosed concept; and

FIG. 22 is a simplified view of a power connector and electricalconnection element therefor, in accordance with another non-limitingembodiment of the disclosed concept.

FIG. 23 is a cross-sectional, isometric view of a power connector with atoggle operating mechanism and an interlock assembly.

FIG. 24 is another cross-sectional, isometric view of a power connectorwith a toggle operating mechanism and an interlock assembly.

FIG. 25 is an isometric view of a toggle operating mechanism in a firstconfiguration.

FIG. 26 is an isometric view of a toggle operating mechanism in a secondconfiguration.

FIG. 27 is a schematic view of a toggle operating mechanism in a firstconfiguration.

FIG. 28 is a schematic view of a toggle operating mechanism between afirst configuration and a second configuration.

FIG. 29 is a schematic view of a toggle operating mechanism in a secondconfiguration.

FIG. 30 is an isometric view of a power connector with an actuatingassembly.

FIG. 31 is another isometric view of a power connector with an actuatingassembly.

FIG. 32 is an isometric view of an actuating assembly.

FIG. 33 is another isometric view of an actuating assembly.

FIG. 34 is a detail isometric view of selected actuating assembly gears.

FIG. 35 is a cross-sectional side view of an interlock assembly in atransition position.

FIG. 36 is a cross-sectional side view of an interlock assembly in asecond position.

FIG. 37 is an isometric view of an interlock assembly locking member andan interlock assembly latching member.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

For purposes of the description hereinafter, directional phrases usedherein such as, for example, “clockwise,” “counterclockwise,” “up,”“down,” and derivatives thereof shall relate to the disclosed concept,as it is oriented in the drawings. It is to be understood that thespecific elements illustrated in the drawings and described in thefollowing specification are simply exemplary embodiments of thedisclosed concept. Therefore, specific orientations and other physicalcharacteristics related to the embodiments disclosed herein are not tobe considered limiting with respect to the scope of the disclosedconcept.

As employed herein, the term “number” shall mean one or an integergreater than one (i.e., a plurality).

As employed herein, the singular form of “a,” “an,” and “the” includeplural references unless the context clearly dictates otherwise.

As employed herein, the term “conductor” shall mean a member, such as acopper conductor, an aluminum conductor, a suitable metal conductor, orother suitable material or object that permits an electric current toflow easily.

As employed herein, the statement that two or more parts are “connected”or “coupled” together shall mean that the parts are joined togethereither directly or joined through one or more intermediate parts. Asused herein, “directly coupled” or “directly connected” means that twoelements are directly in contact with each other. As used herein,“fixedly coupled” or “fixed” means that two components are coupled so asto move as one while maintaining a constant orientation relative to eachother. Accordingly, when two elements are coupled, all portions of thoseelements are coupled. A description, however, of a specific portion of afirst element being coupled to a second element, e.g., an axle first endbeing coupled to a first wheel, means that the specific portion of thefirst element is disposed closer to the second element than the otherportions thereof. Further, an object resting on another object held inplace only by gravity is not “coupled” to the lower object unless theupper object is otherwise maintained substantially in place. That is,for example, a book on a table is not coupled thereto, but a book gluedto a table is coupled thereto.

As used herein, the phrase “removably coupled” means that one componentis coupled with another component in an essentially temporary manner.That is, the two components are coupled in such a way that the joiningor separation of the components is easy and would not damage thecomponents. For example, two components secured to each other with alimited number of readily accessible fasteners, i.e., fasteners that arenot difficult to access, are “removably coupled” whereas two componentsthat are welded together or joined by difficult to access fasteners arenot “removably coupled.” A “difficult to access fastener” is one thatrequires the removal of one or more other components prior to accessingthe fastener wherein the “other component” is not an access device suchas, but not limited to, a door.

As employed herein, the statement that two or more parts or components“engage” one another shall mean that the parts touch and/or exert aforce against one another either directly or through one or moreintermediate parts or components. Further, as used herein with regard tomoving parts, a moving part may “engage” another element during themotion from one position to another and/or may “engage” another elementonce in the described position. Thus, it is understood that thestatements, “when element A moves to element A first position, element Aengages element B,” and “when element A is in element A first position,element A engages element B” are equivalent statements and mean thatelement A either engages element B while moving to element A firstposition and/or element A either engages element B while in element Afirst position.

As used herein, “operatively engage” means “engage and move.” That is,“operatively engage” when used in relation to a first component that isstructured to move a movable or rotatable second component means thatthe first component applies a force sufficient to cause the secondcomponent to move. For example, a screwdriver may be placed into contactwith a screw. When no force is applied to the screwdriver, thescrewdriver is merely “coupled” to the screw. If an axial force isapplied to the screwdriver, the screwdriver is pressed against the screwand “engages” the screw. However, when a rotational force is applied tothe screwdriver, the screwdriver “operatively engages” the screw andcauses the screw to rotate. Further, with electronic components,“operatively engage” means that one component controls another componentby a control signal or current.

As used herein, “operatively coupled” means that a number of elements orassemblies, each of which is movable between a first position and asecond position, or a first configuration and a second configuration,are coupled so that as the first element moves from oneposition/configuration to the other, the second element moves betweenpositions/configurations as well. It is noted that a first element maybe “operatively coupled” to another without the opposite being true.

As used herein, a “coupling assembly” includes two or more couplings orcoupling components. The components of a coupling or coupling assemblyare generally not part of the same element or other component. As such,the components of a “coupling assembly” may not be described at the sametime in the following description.

As used herein, a “coupling” or “coupling component(s)” is one or morecomponent(s) of a coupling assembly. That is, a coupling assemblyincludes at least two components that are structured to be coupledtogether. It is understood that the components of a coupling assemblyare compatible with each other. For example, in a coupling assembly, ifone coupling component is a snap socket, the other coupling component isa snap plug, or, if one coupling component is a bolt, then the othercoupling component is a nut.

As used herein, “correspond” indicates that two structural componentsare sized and shaped to be similar to each other and may be coupled witha minimum amount of friction. Thus, an opening which “corresponds” to amember is sized slightly larger than the member so that the member maypass through the opening with a minimum amount of friction. Thisdefinition is modified if the two components are to fit “snugly”together. In that situation, the difference between the size of thecomponents is even smaller whereby the amount of friction increases. Ifthe element defining the opening and/or the component inserted into theopening are made from a deformable or compressible material, the openingmay even be slightly smaller than the component being inserted into theopening. Further, as used herein, “loosely correspond” means that a slotor opening is sized to be larger than an element disposed therein. Thismeans that the increased size of the slot or opening is intentional andis more than a manufacturing tolerance. With regard to surfaces, shapes,and lines, two, or more, “corresponding” surfaces, shapes, or lines havegenerally the same size, shape, and contours.

As used herein, a “path of travel” or “path,” when used in associationwith an element that moves, includes the space an element moves throughwhen in motion. As such, any element that moves inherently has a “pathof travel” or “path.” When used in association with an electricalcurrent, a “path” includes the elements through which the currenttravels.

As used herein, “structured to [verb]” means that the identified elementor assembly has a structure that is shaped, sized, disposed, coupledand/or configured to perform the identified verb. For example, a memberthat is “structured to move” is movably coupled to another element andincludes elements that cause the member to move or the member isotherwise configured to move in response to other elements orassemblies. As such, as used herein, “structured to [verb]” recitesstructure and not function. Further, as used herein, “structured to[verb]” means that the identified element or assembly is intended to,and is designed to, perform the identified verb. Thus, an element thatis merely capable of performing the identified verb but which is notintended to, and is not designed to, perform the identified verb is not“structured to [verb].”

As used herein, “associated” means that the elements are part of thesame assembly and/or operate together, or, act upon/with each other insome manner. For example, an automobile has four tires and four hubcaps. While all the elements are coupled as part of the automobile, itis understood that each hubcap is “associated” with a specific tire.

As used herein, in the phrase “[x] moves between its first position andsecond position,” or, “[y] is structured to move [x] between its firstposition and second position,” “[x]” is the name of an element orassembly. Further, when [x] is an element or assembly that moves betweena number of positions, the pronoun “its” means “[x],” i.e., the namedelement or assembly that precedes the pronoun “its.”

As used herein, the word “unitary” means a component that is created asa single piece or unit. That is, a component that includes pieces thatare created separately and then coupled together as a unit is not a“unitary” component or body.

As used herein, “about” in a phrase such as “disposed about [an element,point or axis]” or “extend about [an element, point or axis]” or “[X]degrees about an [an element, point or axis],” means encircle, extendaround, or measured around. When used in reference to a measurement orin a similar manner, “about” means “approximately,” i.e., in anapproximate range relevant to the measurement as would be understood byone of ordinary skill in the art.

As used herein, “generally” means “in a general manner” relevant to theterm being modified as would be understood by one of ordinary skill inthe art.

As used herein, “substantially” means for the most part, by a largeamount or degree, as would be understood by one of ordinary skill in theart. Thus, for example, a first element “substantially” disposed in asecond element is, for the most part, disposed in the second element.

As used herein, a “snap-action” means an action resulting fromtemporarily stored mechanical energy being released. As a non-limitingexample, a compressed spring held by a latch which is then releasedprovides a “snap-action.” Similarly, a toggle assembly or elements in atoggle configuration temporarily store mechanical energy as the elementsmove to the toggle point and that energy is released when the elementspass the toggle point or, if the elements are held at, or just past, thetoggle point, the energy is released when the elements reverse directionand move through the toggle point. Thus, as used herein, a “snap-actionmechanism” is a mechanism that operates using a “snap-action.”

FIG. 1 shows a simplified view of a power connector 100, employing anelectrical connection element (e.g., without limitation, line sideelectrical receptacle 110) and an electrical component (e.g., withoutlimitation, load side electrical receptacle 160) in accordance with onenon-limiting example embodiment of the disclosed concept. In the exampleshown, the line side electrical receptacle 110 includes a housing 112that has a number of electrical mating members, such as the examplefemale conductors (e.g., without limitation, sleeves 114,116,118). Theload side electrical receptacle 160 has a housing 162 that has a numberof electrical mating members, such as the example male conductors (e.g.,without limitation, pins 164,166,168).

The load side electrical receptacle 160 is also shown in dashed linedrawing mechanically coupled to the line side electrical receptacle 110.In operation, and as shown in dashed line drawing, each of the pins164,166,168 is located within (i.e., as a result of being inserted into)a corresponding one of the sleeves 114,116,118 in order to mechanicallycouple the load side electrical receptacle 160 to the line sideelectrical receptacle 110. In known power connectors (not shown),inserting pins (not shown) into corresponding sleeves (not shown) mayresult in “hot plugging,” as discussed above. However, in accordancewith the disclosed concept, and as will be discussed in greater detailbelow, the line side electrical receptacle 110 further includes acontact assembly 120 and an operating mechanism (e.g., withoutlimitation, manual operating lever 130) that advantageously allow theswitching energy, which occurs when current first begins to flow freelyor first stops flowing freely, to be located in the contact assembly120, rather than at the connection between the pins 164,166,168 and thesleeves 114,116,118. In this manner, the pins 164,166,168 and thesleeves 114,116,118 are advantageously well-protected againstundesirable melting, and/or being welded together, and/or damage to therespective surfaces, and/or an arc flash.

The contact assembly 120 is enclosed by the housing 112 and iselectrically connected to the sleeves 114,116,118. In the non-limitingexample shown, the manual operating lever 130 is coupled to the housing112 and the contact assembly 120. Furthermore, the manual operatinglever 130 opens and closes the contact assembly 120. The contactassembly 120 is structured to electrically connect and disconnect powerwhen the pins 164,166,168 remain mechanically coupled to (i.e., areinserted within) the sleeves 114,116,118. That is, the pins 164,166,168and the sleeves 114,116,118 engage before the contact assembly 120 isclosed, and disengage after the contact assembly 120 is opened. As aresult, current is prevented from switching directly from (i.e.,“jumping from,” “arcing from”) the sleeves 114,116,118 to the pins164,166,168. Rather, because the pins 164,166,168 and the sleeves114,116,118 are already engaged, current advantageously experiencesrelatively little electrical resistance when flowing from the sleeves114,116,118 to the pins 164,166,168, distinct from known powerconnectors (not shown) in which initial alignment and engagement of pins(not shown) with electrically hot (e.g., electrically live) sleeves (notshown) results in undesirably large electrical arc energy.

A method of operating the power connector 100 includes the steps ofmechanically coupling the pins 164,166,168 to the sleeves 114,116,118(i.e., inserting the pins 164,166,168 into the sleeves 114,116,118);closing the contact assembly 120 in order to electrically connect powerafter the pins 164,166,168 are mechanically coupled to the sleeves114,116,118; and opening the contact assembly 120 in order toelectrically disconnect power while the pins 164,166,168 aremechanically coupled to (i.e., remain inserted within) the sleeves114,116,118. In this manner, the relatively high switching energyassociated with electrically connecting power are advantageously notlocated at the connection between the pins 164,166,168 and the sleeves114,116,118.

FIG. 2 shows the power connector 100 in an alternative simplified viewfor ease of illustration. Specifically, FIG. 2 shows the manualoperating lever 130 in a first position 130A (i.e., an ON position), asecond position 130B (i.e., an OFF position) (shown in dashed linedrawing), and a third position 130C (i.e., an EJECT position) (shown indashed line drawing). When the pins 164,166,168 are mechanically coupledto the sleeves 114,116,118 (FIG. 1), and the manual operating lever 130moves from the ON position 130A toward the OFF position 130B, the manualoperating lever 130 opens the contact assembly 120 (FIG. 1) in order todisconnect power. When the manual operating lever 130 moves from the OFFposition 130B toward the EJECT position 130C, the manual operating lever130 may assist disengagement of the pins 164,166,168 and the sleeves114,116,118 (FIG. 1). Similarly, when the manual operating lever 130moves from the EJECT position 130C toward the OFF position 130B (i.e.,when the contact assembly 120 is open and the pins 164,166,168 are notcompletely coupled to the sleeves 114,116,118), the manual operatinglever 130 may assist engagement of the pins 164,166,168 and the sleeves114,116,118. Finally, when the manual operating lever 130 moves from theOFF position 130B toward the ON position 130A (i.e., when the pins164,166,168 are fully coupled to the sleeves 114,116,118), the manualoperating lever 130 closes the contact assembly 120 (FIG. 1) in order toconnect power.

Moreover, the operating mechanism of the line side electrical receptacle110 provides an interlock that prevents engagement and disengagement ofthe pins 164,166,168 and the sleeves 114,116,118 when the manualoperating lever 130 is in the ON position 130A. That is, when thecontact assembly 120 is closed, the interlock of the manual operatinglever 130 either ensures that the pins 164,166,168 and the sleeves114,116,118 do not become disengaged (i.e., assuming the pins164,166,168 and the sleeves 114,116,118 were engaged to begin with), orensures that the pins 164,166,168 and the sleeves 114,116,118 do notbecome engaged (i.e., assuming the pins 164,166,168 and the sleeves114,116,118 were disengaged to begin with). In one non-limitingembodiment, the interlock includes a pin or rim (not shown) with anexpanded end. In this embodiment, the manual operating lever 130includes a link member (not shown) that blocks the path for therespective pins 164,166,168 or rim (not shown) to prevent engagementwhen the manual operating lever 130 in the ON position 130A.

Furthermore, in this embodiment the operating mechanism latches onto theexpanded end and pulls the pins 164,166,168 and the sleeves 114,116,118together to assist engagement when moving from the EJECT position 130Cto the OFF position 130B. Additionally, the operating mechanism ismaintained on the expanded end to prevent disengagement when the manualoperating lever 130 is in the ON position 130A and pushes against theexpanded end to assist disengagement when moving from the OFF position130B to the EJECT position 130C.

Furthermore, the manual operating lever 130 advantageously opens andcloses the contact assembly 120 by a snap-action mechanism. Morespecifically, in one non-limiting embodiment, the line side electricalreceptacle 110 further includes a number of biasing elements (not shown)that cooperate with the manual operating lever 130 and the contactassembly 120 by releasing stored energy in order to allow the manualoperating lever 130 to rapidly open and close the contact assembly 120.

As seen in the non-limiting example of FIG. 3, the alternative powerconnector 200 includes many of the same components as the powerconnector 100 (FIGS. 1 and 2), and like components are labeled with likereference numerals. However, different from the power connector 100(FIGS. 1 and 2), the load side electrical receptacle 260 includes thecontact assembly 220 and the manual operating lever 230 for opening andclosing the contact assembly 220. The contact assembly 220 iselectrically connected to the pins 264,266,268 and has the same functionas the contact assembly 120. Specifically, when the pins 264,266,268 aremechanically coupled to the sleeves 214,216,218, the contact assembly220 is structured to electrically connect and disconnect power,advantageously allowing the location of the switching energy in thepower connector 200 to be at the contact assembly 220, rather than atthe connection between the pins 264,266,268 and the sleeves 214,216,218.It can thus be appreciated that advantages associated with employing thecontact assembly 120 and the manual operating lever 130 in the line sideelectrical receptacle 110 for the power connector 100 likewise apply toemploying the contact assembly 220 and the manual operating lever 230 inthe load side receptacle 260 for the power connector 200.

As seen in the non-limiting example of FIG. 4, the alternative powerconnector 300 includes many of the same components as the powerconnector 100 (FIGS. 1 and 2), and like components are labeled with likereference numerals. However, the line side electrical receptacle 310includes an electromagnetic apparatus 330 as the operating mechanism foropening and closing the contact assembly 320 instead of the manualoperating lever 130 (FIGS. 1 and 2). The electromagnetic apparatus 330is coupled to the housing 312, and includes an electromagnet coil 332and a manual coil power control switch 333. In operation, while the pins364,366,368 are mechanically coupled to the sleeves 314,316,318, themanual coil power control switch 333 is structured to move between an ONposition and an OFF position in order to connect power and disconnectpower, respectively. When the manual coil power control switch 333 movesto the ON position, power from the line side electrical receptacle 310is provided to the electromagnet coil 332, which advantageously allowsthe contact assembly 320 to rapidly close by a snap-action mechanism andthereby connect power. Similarly, when the manual coil power controlswitch 333 moves to the OFF position, power to the electromagnet coil332 is turned off, thereby rapidly opening the contact assembly 320 by asnap-action mechanism and disconnecting power. It can thus beappreciated that advantages associated with employing the contactassemblies 120,220 and the manual operating levers 130,230 in the powerconnectors 100,200 likewise apply to employing the contact assembly 320and the electromagnetic apparatus 330 in the power connector 300.

As seen in the non-limiting example of FIG. 5, the alternative powerconnector 400 includes many of the same components as the powerconnector 300 (FIG. 4), and like components are labeled with likereference numerals. However, the contact assembly 420 and an operatingmechanism (e.g., without limitation, electromagnetic apparatus 430) foropening and closing the contact assembly 420 are located in the loadside electrical receptacle 460. The electromagnetic apparatus 430 iscoupled to the housing 462, and includes an electromagnetic coil 432 anda number of conductors (see, for example, two coil power pins 434,436)electrically connected to the electromagnetic coil 432. Furthermore, thehousing 412 of the line side electrical receptacle 410 includes anothernumber of conductors (see, for example two coil power sleeves 417,419).In operation, the pins 464,466,468 are first mechanically coupled to thesleeves 414,416,418. Next, the coil power pins 434,436 are engaged with(i.e., inserted into) the coil power sleeves 417,419 in order to providepower to the electromagnetic coil 432 to rapidly close the contactassembly 420 by a snap-action mechanism and thereby connect power.During disengagement, the coil power pins 434,436 are disengaged firstfrom the coil power sleeves 417,419, thereby removing power from theelectromagnetic coil 432 and rapidly opening the contact assembly 420 bya snap-action mechanism, while the pins 464,466,468 remain mechanicallycoupled to the sleeves 414,416,418.

It will be appreciated with reference to FIG. 5 that the pins464,466,468 are structured to extend a greater distance into the housing412 of the line side electrical receptacle 410 than the coil power pins434,436, thereby allowing the pins 464,466,468 and the sleeves414,416,418 to engage before the contact assembly 420 is closed, anddisengage after the contact assembly 420 is opened. As a result, anyelectrical switching within the power connector 400 (i.e., when power isconnected and when power is disconnected) occurs while the pins464,466,468 and the sleeves 414,416,418 are mechanically coupled. Thus,advantages with respect to minimizing “hot plugging” likewise apply tothe power connector 400.

As seen in the non-limiting example of FIG. 6, the alternative powerconnector 500 includes many of the same components as the powerconnector 400 (FIG. 5), and like components are labeled with likereference numerals. However, the electromagnetic apparatus 530, which iscoupled to the housing 562, includes a manual coil power control switch533 that turns power to the electromagnetic coil 532 on and offSpecifically, when the pins 564,566,568 are mechanically coupled to thesleeves 514,516,518, and the coil power pins 534,536 are mechanicallyconnected to (i.e., inserted into) the coil power sleeves 517,519, themanual coil power control switch 533 can either connect power by rapidlyclosing the contact assembly 520 by a snap-action mechanism, ordisconnect power by rapidly opening the contact assembly 520 by asnap-action mechanism. Similar to the power connector 400, the pins564,566,568 are structured to extend a greater distance into the lineside electrical receptacle 510 than the coil power pins 534,536, therebyallowing the pins 564,566,568 and the sleeves 514,516,518 to engagebefore the contact assembly 520 is closed, and disengage after thecontact assembly 520 is opened.

As seen in the non-limiting example of FIG. 7, the alternative powerconnector 600 includes many of the same components as the powerconnector 100 (FIGS. 1 and 2), and like components are labeled with likereference numerals. However, the operating mechanism 630 for opening andclosing the contact assembly 620 is different. Additionally, the housing662 further includes a driving member (e.g., without limitation,mechanical operator 670) that cooperates with the operating mechanism630 to open and close the contact assembly 620.

Referring to the non-limiting example of FIGS. 8A and 8B, a portion ofthe power connector 600 is shown in an alternative simplified view forease of illustration. As shown, the operating mechanism 630 includes afirst sliding member 632, a second sliding member 634, a first biasingelement (e.g., without limitation, spring 636), a second biasing element(e.g., without limitation, spring 638), a third biasing element (e.g.,without limitation, spring 639), and a linking member 640 each coupledto the housing 612. As shown, the spring 636 couples the first slidingmember 632 to the linking member 640. The spring 638 couples the secondsliding member 634 to the contact assembly 620. FIG. 8A shows theoperating mechanism 630 in a first position corresponding to the contactassembly 620 being open. FIG. 8B shows the operating mechanism 630 in asecond position corresponding to the contact assembly 620 being closed.

The operating mechanism 630 moves from the first position (FIG. 8A) tothe second position (FIG. 8B) as a result of the mechanical operator670. More specifically, when the pins 664,666,668 are mechanicallycoupled to (i.e., inserted into) the sleeves 614,616,618 (see, forexample, the pin 666 inserted into the sleeve 616 in FIGS. 8A and 8B),and the line side electrical receptacle 610 and the load side electricalreceptacle 660 are pushed closer together, the mechanical operator 670pushes the first sliding member 632 from the first position (FIG. 8A)toward the second position (FIG. 8B). Similarly, responsive to the firstsliding member 632 moving from the first position (FIG. 8A) toward thesecond position (FIG. 8B), the spring 636 pulls the linking member 640from the first position (FIG. 8A) toward the second position (FIG. 8B).When the linking member 640 moves from the first position (FIG. 8A)toward the second position (FIG. 8B), the linking member 640 drives thesecond sliding member 634, thereby causing the spring 638 to close thecontact assembly 620.

When the mechanical operator 670 moves from the second position (FIG.8B) toward the first position (i.e., when the line side electricalreceptacle 610 and the load side electrical receptacle 660 begin to moveaway from each other, but the pins 664,666,668 remain mechanicallycoupled to (i.e., inserted into) the sleeves 614,616,618), the spring639 pushes the first sliding member 632 toward the first position (FIG.8A), and the spring 636 pulls the linking member 640 away from thecontact assembly 620 in order to drive the second sliding member 634toward the first position (FIG. 8A). When the second sliding member 634moves from the second position (FIG. 8B) toward the first position (FIG.8A), the spring 638 opens the contact assembly 620. Thus, because thepins 664,666,668 remain mechanically coupled to (i.e., inserted into)the sleeves 614,616,618 when the contact assembly 620 opens and closes,switching energies are advantageously focused on the contact assembly620, resulting in the improvements with respect to “hot plugging,”described hereinabove.

As seen in the non-limiting example of FIG. 9, the alternative powerconnector 700 includes many of the same components as the powerconnector 600 (FIGS. 7, 8A, and 8B), and like components are labeledwith like reference numerals. However, different from the powerconnector 600 (FIGS. 7, 8A, and 8B), the housing 712 of the line sideelectrical receptacle 710 includes the mechanical operator 770, and theload side electrical receptacle 760 includes the contact assembly 720and the operating mechanism 730. It will be appreciated that themechanical operator 770 cooperates with the operating mechanism 730 toopen and close the contact assembly 720 in substantially the same mannerin which the mechanical operator 670 (FIGS. 7, 8A, and 8B) cooperateswith the operating mechanism 630 (FIGS. 7, 8A, and 8B) to open and closethe contact assembly 620. Thus, advantages of the power connector 600(FIGS. 7, 8A, and 8B) associated with improvements in terms of “hotplugging” likewise apply to the power connector 700.

As seen in the non-limiting example of FIG. 10, the alternative powerconnector 800 includes many of the same components as the powerconnectors 600,700 (FIGS. 7-9), and like components are labeled withlike reference numerals. However, different from the power connectors600,700 (FIGS. 7-9), the mechanical operator 870 of the power connector800 is movably coupled to the operating mechanism 830 of the load sideelectrical receptacle 860. That is, the mechanical operator 870 and theoperating mechanism 830 are each components of the same receptacle(i.e., the load side electrical receptacle 860). It will be appreciatedthat the mechanical operator 870 cooperates with the operating mechanism830 in substantially the same manner as the mechanical operators 670,770and the operating mechanisms 630,730, described hereinabove.

However, unlike the power connectors 600,700, the mechanical operator870 is driven into the operating mechanism 830 by the housing 812 of theopposing receptacle (i.e., the line side electrical receptacle 810).

Furthermore, it will be appreciated that the pins 864,866,868 extend agreater distance away from the contact assembly 820 than the mechanicaloperator 870. Thus, as the line side electrical receptacle 810 ismechanically coupled to the load side electrical receptacle 860, thepins 864,866,868 will extend into and remain mechanically coupled to therespective sleeves 814,816,818 before the mechanical operator 870engages the housing 812 of the line side electrical receptacle 810(i.e., in order to connect power). Similarly, when the line sideelectrical receptacle 810 is disconnected from the load side electricalreceptacle 860, the pins 864,866,868 will remain mechanically coupled tothe respective sleeves 814,816,818 when the mechanical operator 870disengages the housing 812 of the line side electrical receptacle 810(i.e., and thus disconnects power).

Furthermore, it will be appreciated that the power connector 800advantageously employs a known receptacle (i.e., the line sideelectrical receptacle 810) that requires no modification. Thus,manufacturing of the power connector 800 is simplified as a known lineside electrical receptacle 810 is able to be employed.

As seen in the non-limiting example of FIG. 11A, the alternative powerconnector 900 includes many of the same components as the powerconnector 800 (FIG. 10), and like components are labeled with likereference numerals. However, different from the power connector 800(FIG. 10), the line side electrical receptacle 910 of the powerconnector 900 includes the operating mechanism 930 and the mechanicaloperator 970. The mechanical operator 970 is caused to cooperate withthe operating mechanism 930 by the housing 962 of the load sideelectrical receptacle 960 (i.e., is driven inwardly with respect to thehousing 912 by the housing 962). FIG. 11B shows one non-limiting exampleembodiment, shown schematically, of the mechanical operator 970 and theoperating mechanism 930 of FIG. 11A. The operating mechanism 930includes a housing 932 (shown in simplified form in phantom linedrawing), a first link member 934, a second link member 936, a cam 938,a contact carrier 940, a first biasing element (e.g., contact spring942), and a second biasing element (e.g., cam spring 944). The housing932 is coupled to the housing 912 by any suitable mechanism. The firstlink member 934 couples the mechanical operator 970 to the cam 938. Thesecond link member 936 couples the cam 938 to the contact carrier 940.The contact spring 942 is coupled to the contact carrier 940 and a pairof electrical contacts 921,923 of the contact assembly 920. The camspring 944 is coupled to the housing 932 and the cam 938. The linkmembers 934,936, the cam 938, the contact carrier 940, and the springs942,944 cooperate with one another and with the mechanical operator 970in order to open and close the contact assembly 920.

That is, the first link member 934 the second link member 936, the cam938, the contact spring 942, the cam spring 944, and the contact carrier940 are structured to move between a first position (shown in FIG. 11B)corresponding to the contact assembly 920 being open and a secondposition (not shown) corresponding to the contact assembly being closed.The mechanical operator 970 is structured to drive the first link member934 from the first position to the second position. The first linkmember 934 and the cam spring 944 are structured to drive the cam 938from the first position to the second position. Responsive to the cam938 moving from the first position to the second position, the secondlink member 936 drives the contact carrier 940, thereby causing thecontact spring 942 to close the contact assembly 920 by a mechanism witha snap-action motion.

Stated differently, responsive to movement of the mechanical operator970 (i.e., in the depicted orientation the movement is to the left andis caused by the housing 962), the first link member 934 drives the cam938, causing the cam 938 to rotate. After the cam 938 rotates apredetermined distance (i.e., the rotational distance which places thecam spring 944 in maximum tension), the cam spring 944 rapidly releasesenergy and continues to rotate the cam 938 in the same direction ofrotation. When the cam spring 944 begins to release energy to drive thecam 938, the second link member 936 rapidly drives the contact carrier940 (i.e., in the depicted orientation this is in the downwarddirection) in order to close the contact assembly 920. It will, however,be appreciated that the operating mechanism 930 may be replaced with asuitable alternative operating mechanism, such as the operatingmechanism 630, discussed hereinabove. It will also be appreciated thatthe power connector 900 operates in a similar manner (i.e., pins964,966,968 remaining mechanically coupled to sleeves 914,916,918 whilemechanical operator 970 and housing 962 cause power to connect anddisconnect) as the power connector 800 (FIG. 10). Furthermore, the powerconnector 900 advantageously employs a known receptacle (i.e., load sideelectrical receptacle 960) which requires no modification, therebysimplifying manufacturing. Additionally, the operating mechanism 830(FIG. 10) of the power connector 800 (FIG. 10) may be replaced with theoperating mechanism 930 and cooperate with the mechanical operator 870in substantially the same manner as the operating mechanism 930 and themechanical operator 970 cooperate with one another.

As seen in the non-limiting example of FIG. 12, the alternative powerconnector 1000 includes many of the same components as the powerconnector 100 (FIGS. 1 and 2), and like components are labeled with likereference numerals. However, the contact assembly 1020 of the line sideelectrical receptacle 1010 includes a number of sets of separablecontacts 1021, a corresponding number of vacuum bottles 1022, and acorresponding number of flexible conductors 1023. For ease ofillustration and economy of disclosure only the set of separablecontacts 1021, the vacuum bottle 1022, and the flexible conductor 1023will be described in detail, although it will be appreciated that theother sets of separable contacts, vacuum bottles, and flexibleconductors shown are configured in substantially the same manner. Theset of separable contacts 1021 includes a first contact 1024 and asecond contact 1025. In operation, when the first contact 1024 engagesthe second contact 1025, an electrical pathway is created therebetween.However, the first contact 1024 is structured to move into and out ofengagement with the second contact 1025 in order to open and close thecontact assembly 1020.

More specifically, the operating mechanism is an operating lever 1030that is coupled to each respective first contact 1024 and causes therespective first contacts 1024 to move into and out of engagement withthe respective second contacts 1025. Additionally, the vacuum bottle1022 and the flexible conductor 1023 advantageously allow the firstcontact 1024 to move into and out of engagement with the second contact1025. The vacuum bottle 1022 includes a number of convolutions 1026,1027 that are coupled to the first contact 1024. The convolutions 1026,1027 allow the vacuum bottle 1022 to flex and move with the firstcontact 1024 in response to movement of the operating lever 1030, thusallowing the first contact 1024 and the second contact 1025 to open andclose within the vacuum bottle 1022. Furthermore, the flexible conductor1023 is mechanically coupled to and electrically connected in series inbetween the first contact 1024 and the sleeve 1014 in order to allowmovement of the first contact 1024. As such, when the first contact 1024moves, a mechanical and electrical connection is advantageouslymaintained between the first contact 1024 and the sleeve 1014. Thus, itwill be appreciated that in addition to advantages associated withminimizing “hot plugging” in the power connector 1000 by employing thecontact assembly 1020 and the operating lever 1030, the power connector1000 has the significant additional advantage of achieving arc freeoperation by containing any electrical arcing within the vacuum bottles1022. As a result, oil, gas, and mining industries that employ the powerconnector 1000 are significantly safer, as interaction with a potentialarc and explosive materials is significantly minimized.

As seen in the non-limiting example of FIG. 13, the alternative powerconnector 1100 includes many of the same components as the powerconnector 1000 (FIG. 12), and like components are labeled with likereference numerals. However, the contact assembly 1120 and the operatinglever 1130 are components of the load side electrical receptacle 1160and not the line side electrical receptacle 1110. The operating lever1130 moves the first contact 1124 into and out of engagement with thesecond contact 1125 within the vacuum bottle 1122 in substantially thesame manner as the operating lever 1030 (FIG. 12). Thus, it will beappreciated that advantages associated with minimizing “hot plugging”and achieving arc free operation because of the vacuum bottles likewiseapplies to the power connector 1100.

As seen in the non-limiting example of FIG. 14, the alternative portionof the power connector 1200 includes many of the same components as thepower connectors 1000, 1100 (FIGS. 12 and 13), and like components arelabeled with like reference numerals. However, the operating mechanismof the power connector 1200 includes a biasing element (e.g., spring1230) that is coupled to the first contact 1224 and the sleeve 1214. Inoperation, when the pin 1264 is inserted into the sleeve 1214 and isfully engaged (i.e., is entirely inserted into and/or cannot be pushedinto the sleeve 1214 anymore), the sleeve 1214 is structured to slidewithin the line side electrical receptacle 1210 (partially shown) andcause the spring 1230 to move the first contact 1224 into engagementwith the second contact 1225. That is, the sleeve 1214 movesindependently with respect to the second contact 1225 in order to allowthe spring 1230 to close the contacts 1224, 1225. Similarly, when thepin 1264 is pulled away from the sleeve 1214, the spring 1230 pulls thefirst contact 1224 out of engagement with the second contact 1225,thereby disconnecting power. Because the pin 1264 and the sleeve 1214remain mechanically coupled when the contact assembly 1220 is opened(and also remain coupled when the contact assembly 1220 is closed),advantages associated with minimizing “hot plugging” likewise apply tothe power connector 1200. Similarly, because the first contact 1224 andthe second contact 1225 open and close within the vacuum bottle 1222,beneficial arc free operation is likewise achieved in the powerconnector 1200.

As seen in the non-limiting example of FIG. 15, the alternative powerconnector 1300 includes many of the same components as the powerconnector 1200 (FIG. 14), and like components are labeled with likereference numerals. However, the load side electrical receptacle 1360includes the contact assembly 1320 and the spring 1330. Thus, it will beappreciated that the pin 1364 is structured to slide within the loadside electrical receptacle 1360 and move independently with respect tothe second contact 1325. That is, when the pin 1364 is fully engaged(i.e., cannot be inserted further into) with the sleeve 1314, the sleeve1314 pushes the pin 1364, and thus the spring 1330 is able to move thefirst contact 1324 into engagement with the second contact 1325 toconnect power. Accordingly, advantages associated with “hot plugging”and achieving arc free operation likewise apply to the power connector1300.

As seen in the non-limiting example of FIG. 16, the alternative powerconnector 1400 includes many of the same components as the powerconnector 100 (FIGS. 1 and 2), and like components are labeled with likereference numerals. However, different from the power connector 100(FIGS. 1 and 2), the power connector 1400 further includes an electricalconnection element (e.g., without limitation, adapter 1480) thatmechanically couples and electrically connects the line side electricalreceptacle 1410 to the load side electrical receptacle 1460. The adapter1480 includes a housing 1482 that has a first number of electricalmating members, such as the example male conductors (e.g., withoutlimitation, pins 1484, 1486, 1488) and a second number of electricalmating members, such as the example female conductors (e.g., withoutlimitation, sleeves 1494, 1496, 1498).

Additionally, as shown, the adapter 1480 advantageously includes thecontact assembly 1420 and the operating lever 1430 that opens and closesthe contact assembly 1420. In operation, the pins 1484, 1486, 1488remain mechanically coupled to (i.e., inserted into) and electricallyconnected with the sleeves 1414, 1416, 1418, and the pins 1464, 1466,1468 remain mechanically coupled to (i.e., inserted into) andelectrically connected with the sleeves 1494, 1496, 1498 when theoperating lever 1430 opens and closes the contact assembly 1420. Thus,advantages associated with minimizing “hot plugging” are likewiseprovided for in the power connector 1400. Additionally, the adapter 1480is a separate component from the line side electrical receptacle 1410and the load side electrical receptacle 1460. It will be appreciatedthat the power connector 1400 advantageously employs known receptacles(i.e., the line side electrical receptacle 1410 and the load sideelectrical receptacle 1460) that advantageously require no modification.Thus, manufacturing of the power connector 1400 is advantageouslysimplified and “hot plugging” is minimized.

Accordingly, it will be appreciated that the disclosed concept providesfor an improved (e.g., without limitation, longer-lasting,better-protected from dangerous switching energies) power connector 100,200, 300, 400, 500, 600, 700, 800, 900, 1000, 1100, 1200, 1300, 1400 andelectrical connection element 110, 260, 310, 460, 560, 610, 760, 860,910, 1010, 1160, 1210, 1360, 1480 and associated method therefor, whichamong other benefits, redirects switching energy to a contact assembly120, 220, 320, 420, 520, 620, 720, 820, 920, 1020, 1120, 1220, 1320,1420 in order to minimize the occurrence of “hot plugging” within thepower connector 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000, 1100,1200, 1300, 1400.

In addition to the foregoing, FIG. 17 shows a simplified view of aportion of a non-limiting example power connector 1500 in which anelectrical connection element (e.g., load side electrical receptacle1540) includes an insulative housing 1542 and a mating assembly 1544located on the insulative housing 1542. In the example shown, the lineside electrical receptacle 1510 includes an insulative housing 1512 anda mating assembly 1514 located on the insulative housing 1512. As shown,the mating assembly 1514 includes a number of electrical mating memberssuch as the example female conductors (e.g., phase sleeves 1516, 1518)that are substantially enclosed by the insulative housing 1512.

The mating assembly 1544 includes a number of electrical mating memberssuch as the example male conductors (e.g., phase pins 1546, 1548) thatare structured to be electrically connected to the sleeves 1516, 1518.In the depicted first position of FIG. 17, the load side electricalreceptacle 1540 is spaced from the line side electrical receptacle 1510.In this position, and as will be discussed in greater detail below, thepins 1546, 1548 are advantageously substantially enclosed by theinsulative housing 1542. Thus, the potential for inadvertent contactwith the potentially “hot” pins 1546, 1548 is significantly lessened, asthe pins 1546, 1548 are well protected (i.e., as a result of beingsurrounded by or enclosed by the insulative housing 1542) in thisposition. Also, the power connector 1500 advantageously allows the pins1546, 1548 to move to a second position (shown in FIG. 20) in which thepins 1546, 1548 engage the sleeves 1516, 1518 in order to create anelectrical pathway therebetween and thus connect power. That is, themating assembly 1544 is structured to move between a first position(FIG. 17) corresponding to the pins 1546,1548 being substantiallyenclosed by the insulative housing 1542, and a second position (FIG. 20)corresponding to the pins 1546,1548 being partially located external theinsulative housing 1542.

Continuing to refer to FIG. 17, the mating assembly 1514 of the lineside electrical receptacle 1510 further includes a driving apparatus1520 coupled to the insulative housing 1512. The driving apparatus 1520has a biasing element (e.g., spring 1522) and a ground sleeve 1524. Theground sleeve 1524 is slidably coupled to the insulative housing 1512.Specifically, in operation the ground sleeve 1524 is structured to moveindependently with respect to the insulative housing 1512. Additionally,the insulative housing 1512 has a shelf 1513 and the ground sleeve 1524has a lip 1525 that is structured to engage the shelf 1513. Theinteraction between the lip 1525 of the ground sleeve 1524 and the shelf1513 advantageously allows the ground sleeve to be maintained on theinsulative housing 1512.

The spring 1522 engages the insulative housing 1512 and the groundsleeve 1524 and biases the ground sleeve 1524 in a direction 1566. Themating assembly 1544 of the load side electrical receptacle 1540 furtherincludes a driving apparatus (e.g., ground pin 1550) that is structuredto move in a first direction 1564 and a second direction (i.e., thedirection 1566) opposite the first direction 1564. In operation, and aswill be discussed in greater detail hereinbelow, the ground pin 1550cooperates with the driving apparatus 1520 of the line side electricalreceptacle 1510 in order to move the mating assembly 1544 between thefirst position (FIG. 17) corresponding to the pins 1546, 1548 beingsubstantially enclosed by the insulative housing 1542, and the secondposition (FIG. 20) corresponding to the pins 1546, 1548 being partiallylocated external the insulative housing 1542.

More specifically, the insulative housing 1542 has a generally planarinsulative panel 1543, an annular-shaped peripheral rim 1545, and anumber of insulative receiving portions (see, for example, twoinsulative receiving portions 1552, 1554). The insulative panel 1543 islocated generally internal the peripheral rim 1545 (see, for example,FIG. 18). The peripheral rim 1545 cooperates with the insulative housing1512 of the line side electrical receptacle 1510 to insulate the pins1546,1548, as will be discussed in greater detail below. The receivingportions 1552, 1554 each extend from the panel 1543 toward a respectiveend portion 1560, 1562 of the pins 1546, 1548. The receiving portions1552, 1554 have respective distal portions 1556, 1558 located at theinsulative panel 1543. The pins 1546, 1548 have respective first endportions (i.e., the end portions 1560, 1562) and respective second endportions 1561, 1563 located opposite and distal the respective first endportions 1560, 1562.

As shown, when the mating assembly 1544 is in the first position (FIG.17), the second end portions 1561, 1563 are located between therespective distal portions 1556, 1558 and the respective first endportions 1560, 1562. Although it is within the scope of the disclosedconcept for the second end portions 1561,1563 to be located at theinsulative panel 1543 when the mating assembly 1544 is in the firstposition (FIG. 17), having the second end portions 1561,1563 spaced adistance internal from the insulative panel 1543 provides advantageousadditional protection. Thus, in the depicted first position of FIG. 17(i.e., the position of the power connector 1500 when the line sideelectrical receptacle 1510 and the load side electrical receptacle 1540are spaced apart and not engaging one another), the respective secondend portions 1561, 1563 are substantially enclosed by (i.e., surroundedby and/or do not extend external to) the insulative housing 1542. Itwill thus be appreciated that the panel 1543 and the receiving portions1552, 1554 advantageously provide a protective insulative barrierbetween an operator and the potentially “hot” pins 1546, 1548. This isdistinct from known power connectors (not shown) in which the pins (notshown) are undesirably exposed and pose danger to operators when theyare “hot.” Accordingly, when the load side electrical receptacle 1540 isdisconnected from (i.e., separated from and not engaging) the line sideelectrical receptacle 1510, operators are well protected against risksof inadvertent and dangerous contact with the potentially “hot” pins1546, 1548.

Additionally, the power connector 1500 provides for a snap-actionengagement between the pins 1546,1548 and the sleeves 1516,1518, whichadvantageously minimizes electrical arcing, heat dissipation, andteasing, therefore improving the life expectancy of the power connector1500. More specifically, the mating assembly 1544 further includes alink assembly 1570 that has a number of linking members 1572,1574 and anumber of biasing elements (e.g., springs 1576,1578). The linkingmembers 1572, 1574 are each coupled to a respective one of the first endportions 1560, 1562. Furthermore, the linking members 1572, 1574 eachcouple a respective one of the pins 1546,1548 to the ground pin 1550,and cooperate with the pins 1546,1548 and the ground pin 1550, as willbe described in greater detail below. The springs 1576, 1578 are eachlocated on a corresponding one of the linking members 1572, 1574. Morespecifically, the linking members 1572, 1574 preferably, but withoutlimitation, extend through the springs 1576, 1578. When the matingassembly 1544 is in the first position (FIG. 17), the springs 1576, 1578exert respective biases in respective directions 1580, 1582 on therespective pins 1546, 1548 in order to maintain the pins 1546, 1548 inthe first position. In the first position (FIG. 17), the respectivedirections 1580, 1582 are into the load side electrical receptacle 1540.In other words, when the load side electrical receptacle 1540 is in thefirst position (FIG. 17), the springs 1576, 1578 bias the pins 1546,1548 toward, and thus maintain the pins 1546, 1548 in, the firstposition (FIG. 17). This advantageously ensures that the potentially“hot” pins 1546, 1548 remain internal, and are thus protected by, theinsulative housing 1542.

As shown in FIG. 18, the mating assembly 1544 further includes anothermale conductor (e.g., phase pin 1547) that is structured to beelectrically connected to a corresponding sleeve (not shown) of the lineside electrical receptacle 1510 (FIGS. 17, 19 and 20). Thus, it will beappreciated that the pin 1547 is coupled to the ground pin 1550 by wayof another linking member (not shown) of the link assembly 1570 and isbiased toward the first position (FIG. 17) by another correspondingbiasing element (not shown) of the link assembly 1570 in substantiallythe same manner in which the springs 1576, 1578 bias the pins 1546, 1548toward the first position (FIG. 17). It will be appreciated that whilethe disclosed concept herein is being described in association with thethree phase pins 1546, 1547, 1548, a suitable alternative powerconnector (not shown) may include any number of pins without departingfrom the scope of the disclosed concept. Continuing to refer to FIG. 18,the panel 1543 connects each of the receiving portions 1552, 1554 (andthe corresponding receiving portion of the pin 1547, shown but notindicated) to one another. As a result, the panel 1543 significantlyobstructs entry into the load side electrical receptacle 1540.Furthermore, because the pins 1546, 1547 (FIG. 18), 1548 are behind thepanel 1543 (i.e., are spaced a distance internal and/or spaced adistance from a top surface of the panel 1543), the potential forinadvertent dangerous contact is significantly lessened.

It will be appreciated that a method of assembling the power connector1500 includes the steps of: providing the load side electricalreceptacle 1540; providing the line side electrical receptacle 1510;aligning the sleeves 1516, 1518 with the pins 1546, 1547 (FIG. 18),1548; aligning the ground pin 1550 with the ground sleeve 1524; pushing(i.e., inserting) the ground pin 1550 into the ground sleeve 1524,thereby causing the pins 1546, 1547 (FIG. 18), 1548 to moveindependently with respect to the insulative housing 1542 and bepartially located external the insulative housing 1542; and mechanicallyengaging the sleeves 1516, 1518 with the pins 1546, 1547 (FIG. 18),1548. The method further includes the step of driving the ground sleeve1524 in the first direction 1564 into the insulative housing 1512 untilthe spring 1522 drives the ground sleeve 1524 in the second direction1566 opposite the first direction 1564. Thus, it will be appreciatedthat when the mating assembly 1544 moves from the first position (FIG.17) to the second position (FIG. 20), the pins 1546, 1547 (FIG. 18),1548slide at least partially through the corresponding distal portions 1556,1558 in order to be at least partially located external the insulativehousing 1542.

FIG. 19 shows the mating assembly 1544 in a third position between thefirst position (FIG. 17) and the second position (FIG. 20). In thisposition, the around pin 1550 has been inserted into the ground sleeve1524 and has caused the ground sleeve 1524 to move independently withrespect to the insulative housing 1512. Specifically, the ground sleeve1524 has slid into the insulative housing 1512, thus being more enclosedby the insulative housing 1512 in the third position (FIG. 19) than thefirst position (FIG. 17). As a result, the spring 1522 is caused tocompress. As the around pin 1550 is being driven into the ground sleeve1524, the ground pin 1550 is moving in the first direction 1564. Whenthe ground pin 1550 moves in the first direction 1564, the matingassembly 1544 moves from the first position (FIG. 17) toward the thirdposition (FIG. 19). When the ground pin 1550 moves in the seconddirection 1566, the mating assembly 1544 moves from the third position(FIG. 19) toward the second position (FIG. 20).

The compressed spring 1522 assists in moving the mating assembly 1544from the third position (FIG. 19) toward the second position (FIG. 20).That is, when the mating assembly 1544 moves from the first position(FIG. 17) toward the third position (FIG. 19), the ground pin 1550drives the ground sleeve 1524 in the first direction 1564 into theinsulative housing 1512. When the mating assembly 1544 moves from thethird position (FIG. 19) toward the second position (FIG. 20), thespring 1522 drives the ground sleeve 1524 in the second direction 1566into the ground pin 1550 in order to force each of the pins 1546, 1547(FIG. 18), 1548 into a corresponding one of the sleeves 1516, 1518 by amechanism with a snap-action motion.

In addition to the force of the spring 1522, the springs 1576, 1578advantageously assist in causing the mating assembly 1544 to movebetween positions by a mechanism with a snap-action motion.Specifically, as shown in the depicted orientation of FIG. 19 (i.e., thethird position), the linking members 1572, 1574, and thus the springs1576, 1578 have moved to a horizontal position. It will be appreciatedthat when the springs 1576, 1578 are in the horizontal position (i.e.,the third position, specifically where the springs 1576, 1578 areoriented perpendicularly with respect to the pins 1546, 1547 (FIG. 18),1548), the springs 1576, 1578 do not exert any bias on the respectivepins 1546, 1547 (FIG. 18), 1548 in either the respective directions1580, 1582 or in respective directions 1581, 1583 opposite therespective directions 1580, 1582.

When the mating assembly 1544 moves from the first position (FIG. 17)toward the second position (FIG. 20), the spring 1522, and the springs1576,1578, pass an equilibrium position (i.e., the third position ofFIG. 19). Instantly after passing the equilibrium position (i.e., thethird position of FIG. 19), the spring 1522 and the springs 1576, 1578drive the mating assembly 1544 to the second position (FIG. 20). Thatis, the spring 1522 releases stored energy and drives the ground sleeve1524 into the ground pin 1550, which causes the linking members 1572,1574 to move beyond the third position (FIG. 19). Specifically, thelinking members 1572, 1574 are pivotably coupled to the ground pin 1550.Thus, when the mating assembly 1544 moves from the third position (FIG.19) toward the second position (FIG. 20), the linking members 1572, 1574continue to rotate (i.e., in the depicted orientation the linking member1572 rotates in the clockwise direction, and the linking member 1574rotates in the counterclockwise direction).

While the linking members 1572, 1574 are rotating between positions(i.e., from the first position toward the third position, and from thethird position toward the second position), the springs 1576, 1578 arestoring and releasing energy. That is, when the mating assembly 1544moves from the first position (FIG. 17) toward the third position (FIG.19), the springs 1576, 1578 compress and store energy. When the matingassembly 1544 moves from the third position (FIG. 19) toward the secondposition (FIG. 20), the stored energy of the springs 1576, 1578 is ableto be released and drive the pins 1546, 1547 (FIG. 18), 1548 into thesleeves 1516, 1518 by a mechanism with a snap-action motion.Accordingly, it will be appreciated that the driving step of theassembly method further includes the step of releasing the stored energyof the springs 1576, 1578 when the ground sleeve 1524 begins to move inthe second direction 1566, thereby forcing each of the pins 1546, 1547(FIG. 18), 1548 into engagement with sleeves 1516, 1518. Referring toFIG. 20, it will be appreciated that when the mating assembly 1544 is inthe second position, the springs 1576, 1578 exert respective biases onthe respective pins 1546, 1547 (FIG. 18), 1548 in the respectivedirections 1581, 1583 opposite the directions 1580, 1582 in order tomaintain the pins 1546, 1547 (FIG. 18), 1548 in the second position.

In order to allow the mating assembly 1544 to move between positions,the link assembly 1570 further includes a number of sliding members1584, 1586 each coupled to a corresponding one of the pins 1546, 1547(FIG. 18), 1548, and at least one other sliding member 1585 coupled tothe ground pin 1550. The linking members 1572, 1574 each have arespective first end portion 1588,1590 and a respective second endportion 1589, 1591 located opposite and distal the respective first endportion 1588, 1590. The first end portions 1588, 1590 each have arespective slot (for ease of illustration, only slot 1593 of the firstend portion 1590 is depicted) that (via the sliding member 1585) allowsthe first end portions 1588, 1590 to be pivotably coupled to the groundpin 1550. The second end portions 1589, 1591 each have a respective slot1592, 1594. In operation, each sliding member 1584, 1585, 1586 isstructured to slide within a respective slot 1592, 1593, 1594 (and theslot of the first end portion 1588) in order to allow the matingassembly 1544 to move between the first position (FIG. 17) and thesecond position (FIG. 20). Additionally, the linking members 1572, 1574each have a respective pivoting location 1577, 1579 located generallymidway between the respective first end portions 1588, 1590 and thesecond end portions 1589, 1591. It will be appreciated that when themating assembly 1544 moves between positions, the pivoting locations1577, 1579 remain fixed with respect to the insulative housing 1542.That is, the linking members 1572, 1574 rotate about (i.e., with respectto) the pivoting locations 1577, 1579.

The insulative housing 1512 of the line side electrical receptacle 1510includes an annular-shaped insulative receiving portion 1515 having aslot 1517. As shown in FIG. 20, when the pins 1546, 1547 (FIG. 18), 1548have been inserted into the sleeves 1516, 1518, the peripheral rim 1545extends into the slot 1517 and advantageously provides a protectivebarrier against inadvertent contact with the electrically connected pins1546, 1547 (FIG. 18), 1548. Additionally, when the mating assembly 1544is in this second position, each of the pins 1546, 1547 (FIG. 18), 1548extends into a corresponding one of the sleeves 1516,1518 in order toelectrically connect the line side electrical receptacle 1510 to theload side electrical receptacle 1540.

Additionally, although the disclosed concept has been described inassociation with the mating assembly 1544 moving between positions inorder to allow the pins 1546, 1547 (FIG. 18), 1548 to be inserted intothe sleeves 1516, 1518, it will be appreciated that a suitablealternative power connector (not shown) may employ the load sideelectrical receptacle 1540 and another electrical component thatincludes phase pins (not shown) that mechanically engage the pins 1546,1547 (FIG. 18), 1548 instead of sleeves, without departing from thescope of the disclosed concept.

Accordingly, it will be appreciated that the disclosed concept providesfor an improved (e.g., without limitation, better-protected,longer-lasting) power connector 1500, and electrical connection element1540 and assembly method therefor, which among other benefits, enclosespotentially “hot” pins 1546, 1547, 1548 within an insulative housing1542, thereby protecting operators from dangers associated withinadvertent exposure to the pins 1546, 1547, 1548. Additionally, becauseassembly of the power connector 1500 involves a mechanism with asnap-action motion, life expectancy of the power connector 1500 isimproved, as electrical arcing, heat dissipation, and teasing are allminimized.

In addition to the foregoing, FIG. 21 shows one non-limiting exampleembodiment of an alternative power connector 1600 which includes many ofthe same components as the power connector 100 (FIGS. 1 and 2), and manyof the components are labeled with like reference numbers. As shown, thecontact assembly 1620 includes a number of sets of separable contacts1622, 1624, 1626 that are each electrically connected to at least one ofthe sleeves 1614, 1616, 1618. However, in addition to including thecontact assembly 1620, the line side electrical receptacle 1610 furtherincludes an arc suppression system 1630 that advantageously suppressesarcing in the line side electrical receptacle 1610 when the contactassembly 1620 moves between an OPEN position and a CLOSED position.

The arc suppression system 1630 preferably includes a number ofelectronic devices such as the example SCRs 1631, 1633, 1635, 1637,1639, 1641, and a control mechanism 1644 for controlling the SCRs 1631,1633, 1635, 1637, 1639, 1641. Although the concept disclosed herein isbeing described in association with the SCRs 1631, 1633, 1635, 1637,1639, 1641 as the electronic devices, it will be appreciated that anysuitable alternative electronic device (e.g., FETs and/or IGBTs) (notshown) may be employed without departing from the scope of the disclosedconcept. In operation, when the contact assembly 1620 moves between theOPEN position and the CLOSED position, the control mechanism 1644redirects current from each of the sets of separable contacts 1622,1624, 1626 to a corresponding one of the SCRs 1631, 1633, 1635, 1637,1639, 1641 in order to suppress arcing across the respective sets ofseparable contacts 1622, 1624, 1626.

More specifically, the SCRs 1631, 1633, 1635, 1637, 1639, 1641 carrycurrent with a voltage significantly smaller than typical arc voltage.For example and without limitation, the SCRs 1631, 1633, 1635, 1637,1639,1641 preferably carry current with a voltage of around 1 volt,whereas the voltage over an arc is generally greater than 12 volts.Because current follows the path of least resistance, the current willbe redirected from the respective sets of separable contacts 1622, 1624,1626 to the respective SCRs 1631, 1633, 1635, 1637, 1639, 1641. Thus, itwill be appreciated that the arc suppression system 1630 ensures thatthe sets of separable contacts 1622, 1624, 1626 do not have to withstandsignificant arcing. Accordingly, the arc suppression system 1630advantageously allows the size of the sets of separable contacts 1622,1624, 1626 to be relatively small because arc erosion across the sets ofseparable contacts 1622, 1624, 1626 is significantly lessened. As aresult, material can be saved and costs thereby reduced.

Each of the SCRs 1631, 1633, 1635, 1637, 1639, 1641 has a respectivegate 1632, 1634, 1636, 1638, 1640, 1642. The control mechanism 1644includes a gate control circuit 1646 and an operating mechanism (e.g.,without limitation, operating lever 1648). The gate control circuit 1646is structured to move each of the respective gates 1632, 1634, 1636,1638, 1640, 1642 between an ON position and an OFF position in order toredirect current from the respective sets of separable contacts 1622,1624, 1626 to a corresponding one of the SCRs 1631, 1633, 1635, 1637,1639, 1641. The gate control circuit 1646 causes the gates 1632, 1634,1636, 1638, 1640, 1642 to move between positions in response to any oneof a number of input control signals, which include, for example, theposition of the operating lever 1648, current magnitude, voltage acrossthe separable contacts 1622, 1624, 1626, and/or time duration after theSCR's 1631, 1633, 1635, 1637, 1639, 1641 have been turned ON.

For example, when the sleeves 1614, 1616, 1618 and the pins 1664, 1666,1668 are engaged, and the separable contacts 1622, 1624, 1626 movebetween the OPEN position and the CLOSED position, a bounce and an arcvoltage is produced, which sends a signal to the gate control circuit1646 to cause the gates 1632, 1634, 1636, 1638, 1640, 1642 to move fromthe OFF position to the ON position. Furthermore, a timer signal causesthe gates 1632, 1634, 1636, 1638, 1640, 1642 to move to the OFF positionafter the current is carried by the SCR's 1631, 1633, 1635, 1637, 1639,1641. Thus, at the instant when the contact assembly 1620 moves betweenthe OPEN position and the CLOSED position (i.e., to disconnect power orto connect power, responsive to actuation of the operating lever 1648after the sleeves 1614, 1616, 1618 and the pins 1664, 1666, 1668 havebeen mechanically coupled and electrically connected, as discussedabove), the gate control circuit 1646 redirects current to a respectiveone of the SCRs 1631, 1633, 1635, 1637, 1639, 1641. In this manner,arcing across the respective sets of separable contacts 1622, 1624, 1626is advantageously suppressed.

The operating lever 1648, which in the example shown, is coupled to thehousing 1612 of the line side electrical receptacle 1610, is structuredto move the contact assembly 1620 between the OPEN position and theCLOSED position. Additionally, the operating lever 1648 has a sensor1650 that is structured to monitor circuit status of the contactassembly 1620. The sensor 1650 is electrically connected to the gatecontrol circuit 1646 (e.g., without limitation, wirelessly connected) inorder to provide indication of circuit status to the gate controlcircuit 1646. In other words, when the operating lever 1648 opens orcloses the contact assembly 1620, the sensor 1650 sends a signal to thegate control circuit 1646, which in turn causes each of the respectivegates 1632, 1634, 1636, 1638, 1640, 1642 to move from the OFF positionto the ON position in order for current to be redirected and arcing tobe advantageously suppressed.

Additionally, the housing 1612 of the line side electrical receptacle1610 further includes a number of power cables 1613, 1615, 1617 eachelectrically connected to a corresponding one of the sleeves 1614, 1616,1618. The gate control circuit 1646 is electrically connected to atleast one of the power cables 1613, 1615, 1617 in order to be poweredthereby. In this manner, the gate control circuit 1646 is advantageouslyable to be powered by the line side electrical receptacle 1610 withoutthe need to employ a separate powering mechanism.

The line side electrical receptacle 1610 allows current to flow in twoopposing directions (i.e., in a first direction out of the line sideelectrical receptacle 1610 and into the load side electrical receptacle1660, and in a second direction into the line side electrical receptacle1610 from the load side electrical receptacle 1660). Additionally, theSCRs 1631, 1633, 1635, 1637, 1639, 1641 are electrically connected inparallel with the sets of separable contacts 1622, 1624, 1626. Morespecifically, each of the respective first SCRs 1631, 1635, 1639 areelectrically connected in parallel with a respective one of the secondSCRs 1633, 1637, 1641 and a respective one of the sets of separablecontacts 1622, 1624, 1626. Thus, responsive to current flowing in thefirst direction from the line side electrical receptacle 1610 into theload side electrical receptacle 1660, current is redirected into thefirst SCRs 1631, 1635, 1639 when the contact assembly 1620 moves betweenthe OPEN position and the CLOSED position. Similarly, responsive tocurrent flowing in the second direction from the load side electricalreceptacle 1660 into the line side electrical receptacle 1610, currentis redirected into the second SCRs 1633, 1637, 1641 when the contactassembly 1620 moves between the OPEN position and the CLOSED position.Although the concept disclosed herein is being described in associationwith two respective SCRs electrically connected in parallel to one setof separable contacts, it will be appreciated that a single SCR (notshown) could be electrically connected in parallel to a single set ofseparable contacts (not shown) in a suitable alternative power connector(e.g., without limitation, a power connector for direct current with afixed polarity, not shown).

Additionally, an associated method of suppressing arcing in the powerconnector 1600 includes the steps of: providing the load side electricalreceptacle 1660; providing the line side electrical receptacle 1610;electrically connecting the pins 1664, 1666, 1668 to the sleeves 1614,1616, 1618; moving the contact assembly 1620 between an OPEN positionand a CLOSED position; and redirecting current with the controlmechanism 1644 from the respective sets of separable contacts 1622,1624, 1626 to a corresponding one of the SCRs 1631, 1633, 1635, 1637,1639, 1641. Furthermore, the redirecting step includes moving therespective gates 1632, 1634, 1636, 1638, 1640, 1642 from an OFF positionto an ON position in order to redirect current from the respective setsof separable contacts 1622, 1624, 1626 to the corresponding one of theSCRs 1631, 1633, 1635, 1637, 1639, 1641. The example method alsoincludes the steps of: moving the contact assembly 1620 between the OPENposition and the CLOSED position with the operating lever 1648; sendinga signal to the gate control circuit 1646 with the sensor 1650 in orderto provide a circuit status indication; and either (a) redirectingcurrent with the control mechanism 1644 from the respective sets ofseparable contacts 1622, 1624, 1626 to the first SCRs 1631,1635,1639when current flows in the first direction, or (b) redirecting currentwith the control mechanism 1644 from the respective sets of separablecontacts 1622, 1624, 1626 to the second SCRs 1633, 1637, 1641 whencurrent flows in the second direction.

In addition to the foregoing, FIG. 22 shows another non-limiting exampleembodiment of an alternative power connector 1700 which includes many ofthe same components as the power connector 1600 (FIG. 21), and likecomponents are labeled with like reference numbers. As shown, the arcsuppression system 1730 is located in the load side electricalreceptacle 1760. Furthermore, the housing 1762 of the load sideelectrical receptacle 1760 includes a number of electrical matingmembers, such as the example male conductors (e.g., without limitation,power pins 1770, 1772) electrically connected to the gate controlcircuit 1746. The line side electrical receptacle 1710 also includes anumber of electrical mating members, such as the example femaleconductors (e.g., without limitation, power sleeves 1754, 1756), and apowering device 1752. The powering device 1752 is electrically connectedto the power cables 1713, 1715, 1717 and the power sleeves 1754, 1756,and is operable to transfer power from the power cables 1713, 1715, 1717to the power sleeves 1754, 1756.

In operation, each of the power sleeves 1754, 1756 is electricallyconnected to a corresponding one of the power pins 1770, 1772, therebyallowing the power cables 1713, 1715, 1717 (i.e., by way of the poweringdevice 1752) to provide power to the gate control circuit 1746. It willbe appreciated that the arc suppression system 1730 providessubstantially the same advantages for the load side electricalreceptacle 1760 as the arc suppression system 1630 (FIG. 21) providesfor the line side electrical receptacle 1610 (FIG. 21). That is, whenthe contact assembly 1720 moves between the OPEN position and the CLOSEDposition (i.e., responsive to movement of the operating lever 1748), thegate control circuit 1746 redirects current to the SCRs 1731, 1733,1735, 1737, 1739, 1741 in order to advantageously suppress arcing acrossthe respective sets of separable contacts 1722, 1724, 1726. Accordingly,arc suppression of a contact assembly (i.e., the contact assemblies1620, 1720) is advantageously able to be achieved in a line sideelectrical receptacle (i.e., the line side electrical receptacle 1610)and a load side electrical receptacle (i.e., the load side electricalreceptacle 1760).

Additionally, although the power connectors 1600, 1700 have beendescribed in association with the operating levers 1648, 1748 as theoperating mechanisms, it will be appreciated that a suitable alternativepower connector (not shown) may employ a suitable alternative operatingmechanism (i.e., the operating mechanisms 330, 430, 630, 830, 930described above) in order to perform the desired function of opening andclosing a respective contact assembly (not shown). Furthermore, althoughthe arc suppression systems 1630, 1730 have been described inassociation with the line side electrical receptacle 1610 and the loadside electrical receptacle 1760, respectively, it will be appreciatedthat a suitable alternative arc suppression system (not shown) could beemployed with a suitable alternative adapter (not shown) that issubstantially similar to the adapter 1480 (FIG. 16).

Accordingly, it will be appreciated that the disclosed concept providesfor an improved (e.g., without limitation, longer-lasting,better-protected, less expensive) power connector 1600, 1700, andelectrical connection receptacle 1610, 1760 and arc suppression methodtherefor, which among other benefits, redirects current from arespective set of separable contacts 1622, 1624, 1626, 1722, 1724, 1726to a respective electronic device 1631, 1633, 1635, 1637, 1639, 1641,1731, 1733, 1735, 1737, 1739, 1741 in order to advantageously suppressarcing across the respective sets of separable contacts 1622, 1624,1626, 1722, 1724, 1726. Thus, the size of each of the respective sets ofseparable contacts 1622, 1624, 1626, 1722, 1724, 1726 can advantageouslybe made relatively small due to the significantly reduced arc erosion,thereby saving material and reducing cost.

In another exemplary embodiment, shown in FIGS. 23-25 as well asschematically in FIGS. 27-29, the contact assembly 120 (shownschematically in FIG. 1) includes, and is structured to be open andclosed by, a toggle operating mechanism 2000. As with the embodimentsdescribed above, the contact assembly 120, and therefore the toggleoperating mechanism 2000, may be disposed in either the line sideelectrical receptacle 110 or the load side electrical receptacle 160.That is, the contact assembly 120, and therefore the toggle operatingmechanism 2000, may be disposed in either the line side electricalreceptacle housing 112 or the load side electrical receptacle housing162. As such, the housings 112, 162 shall be identified hereinafter, andas used herein, as an elongated “housing 1800,” See FIGS. 1, 23 and 24.It is understood that “housing 1800” is either the line side electricalreceptacle housing 112 or the load side electrical receptacle housing162. Alternatively, the either the line side electrical receptaclehousing 112 and the load side electrical receptacle housing 162 areidentified, as used herein, as the “power connector first housing 1802,”or “first housing 1802,” and the “power connector second housing 1804,”or “second housing 1804.” When using these terms it is understood thatwhen one of the line side electrical receptacle housing 112 or the loadside electrical receptacle housing 162 is identified as the “firsthousing 1802,” then the other of the line side electrical receptaclehousing 112 or the load side electrical receptacle housing 162 isidentified as the “second housing 1804.”

Further, as shown in FIGS. 1 and 27-29, the contact assembly 120includes a number of line-side contacts 122, a number of load-sidecontacts 124, and a number of movable conductor members 126. Eachconductor member 126 is associated with one line-side contact 122 andone load-side contact 124. That is, each conductor member 126 isassociated with a pair of contacts 122, 124 wherein the pair of contactsincludes one line-side contact 122 and one load-side contact 124. Eachconductor member 126 is movable between a first position, wherein theassociated line-side contact 122 and the associated load-side contact124 are not electrically connected, and a second position, wherein theassociated line-side contact 122 and the associated load-side contact124 are electrically connected. Thus, the contact assembly 120 isstructured to electrically connect and disconnect power while the numberof first electrical mating members, e.g., pins 164, 166, 168, remainmechanically coupled to the number of second electrical mating members,e.g., sleeves 114, 116, 118. A problem with prior art contact assembliesis that the conductor members do not move between the first and secondposition rapidly. The disclosed toggle operating mechanism 2000 solvesthis problem.

The toggle operating mechanism 2000 is structured to open and close thecontact assembly 120. In an exemplary embodiment, the toggle operatingmechanism 2000 is a snap-action mechanism that is structured to open andclose the contact assembly 120 by a snap-action. As shown in FIGS.27-29, the toggle operating mechanism 2000 includes a toggle linkage2002. The toggle linkage 2002 defines a “line of action” 2004 and a“toggle line” 2006. As used herein, a “line of action,” when used inrelation to a toggle assembly, means a line of force or bias acting onthe toggle elements of a toggle assembly. As used herein, a “toggleline” is a line defined by the pivot points of the toggle elements of atoggle assembly. As is known, and as used herein, the “line of action,”is disposed on either first side of the “toggle line,” a second side ofthe “toggle line,” or is on, or aligned with, the “toggle line.” As usedherein, and as shown in the figures, the “first side” and “second side”are relative to the “toggle line” when viewed from a position generallyon, or parallel to, the axis of rotation between the toggle elements ofa toggle assembly. As is known, when the “line of action” is disposed ona first side of the “toggle line,” the toggle elements of a toggleassembly collapse in a first configuration. Conversely, when the “lineof action” is disposed on a second side of the “toggle line,” the toggleelements of a toggle assembly collapse in a second configuration. Whenthe “line of action” is disposed on, or aligned with, the “toggle line,”the toggle elements of a toggle assembly do not collapse. It is noted,however, that the toggle elements of a toggle assembly are rarelydisposed exactly on, or aligned with, the “toggle line.” Further, it isunderstood that when the toggle elements of a toggle assembly aremoving, e.g., from a configuration wherein the “line of action” isdisposed on a first side of the “toggle line” toward the “toggle line,”when the “line of action” is disposed on, or aligned with, the “toggleline,” the momentum of the elements carry the toggle elements of atoggle assembly to a configuration wherein the “line of action” isdisposed on a second side of the “toggle line.” Further, as used herein,the “line of action,” i.e., the force/bias, may be generated by a biaselement, such as but not limited to a spring, or, by the configurationof the toggle elements of a toggle assembly. That is, as is known, andin an exemplary embodiment (not shown), the toggle elements of a toggleassembly interact with each other in a manner wherein force is generatedtherebetween.

In an exemplary embodiment, shown best in schematic FIGS. 27-29, thetoggle linkage 2002 is operatively coupled to the conductor members 126and is structured to move the conductor members 126 between the firstand second positions. That is, the toggle linkage 2002 is movablebetween a first configuration, wherein each conductor member is in itsfirst position, and a second configuration wherein, each conductormember is in its second position. Thus, when the toggle linkage line ofaction 2004 is on a first side of the toggle line 2006, the togglelinkage 2002 is biased toward the toggle linkage 2002 firstconfiguration, when the toggle linkage line of action 2004 is on asecond side of the toggle line 2006, the toggle linkage 2002 is biasedtoward the toggle linkage 2002 second configuration. Further, when thetoggle linkage line of action 2004 moves from one side of the toggleline in a direction to align with the toggle line 2006, the togglelinkage line of action 2004 continues to move in the same directionuntil the toggle linkage line of action 2004 is on the other side of thetoggle line 2006. That is, as used herein, “when the toggle linkage lineof action 2004 moves from one side of the toggle line in a direction toalign with the toggle line 2006, the toggle linkage line of action 2004continues to move in the same direction until the toggle linkage line ofaction 2004 is on the other side of the toggle line 2006” means thatwhen the toggle linkage line of action 2004 is on the first side of thetoggle line 2006 and moves in a direction to aligned with the toggleline 2006, the toggle linkage line of action 2004 continues to move inthe same direction until the toggle linkage line of action 2004 is onthe second side of the toggle line 2006, and, when the toggle linkageline of action 2004 is on the second side of the toggle line 2006 andmoves in a direction to align with the toggle line 2006, the togglelinkage line of action 2004 continues to move in the same directionuntil the toggle linkage line of action 2004 is on the first side of thetoggle line 2006.

In an exemplary embodiment, the toggle operating mechanism 2000, andmore specifically the toggle linkage 2002, includes a “knee joint” 2010.As used herein, a “knee joint” means an assembly of two elongated rigidelements that are rotatably coupled to each other. Further, in anexemplary embodiment, the toggle operating mechanism knee joint 2010,hereinafter, “knee joint” 2010, includes an elongated upper link 2020and an elongated lower link 2030. The upper link 2020 includes a firstend 2022 and a second end 2024. In an exemplary embodiment, the upperlink first end 2022 is coupled, directly coupled, or rotatably coupledto the housing 1800 (coupling not visible in the Figures).

Further, in an exemplary embodiment (not shown), upper link first end2022 is attached to the housing 1800 or to an interlock trippingassembly (not shown). The interlock tripping assembly is, in anexemplary embodiment, a sliding or rotating member (not shown) that isheld in a fixed first position when the line side electrical receptacle110 is connected to the load side electrical receptacle 160. In thefirst position upper link first end 2022 is, generally, in the positionshown in FIG. 27 and the toggle operating mechanism 2000 is capable ofperforming the snap action closing and opening of the contact member126. When the two receptacles are parted, the interlock trippingassembly tripping member moves to a second position which causes thefirst position upper link first end 2022 to move and to change the angleof toggle line 2006. This change in the toggle line makes the toggleoperating mechanism 2000 unstable in the second position (contactsclosed position). If the contacts are closed at the moment that the tworeceptacles are parted, the movement of the interlock trip feature takesthe end 2022 to the other side of the line of action 2004, thus causingthe toggle operating mechanism 2000 to move to the first position andopen the contacts 122, 124. This interlock tripping feature alsoprevents the toggle operating mechanism 2000 from moving to the secondposition (contacts closed) if the two receptacles 110, 160 are notconnected.

The lower link 2030 includes a first end 2032 and a second end 2034. Theupper link second end 2024 is rotatably coupled to the lower link firstend 2032. In an exemplary embodiment, the upper link second end 2024 andthe lower link first end 2032 each include an opening (not shown). Inthis embodiment, the knee joint 2010 also includes a knee pin 2012 thatextends through the openings in the upper link second end 2024 and thelower link first end 2032. The toggle line 2006 extends through the kneepin 2012.

The lower link second end 2034 is rotatably coupled, or rotatablydirectly coupled, to the conductor member(s) 126. In an exemplaryembodiment, the contact assembly 120 also includes a frame assembly 140,a number of slider members 142 and a number of contact springs 144(FIGS. 27-29). The contact assembly frame assembly 140 is coupled,directly coupled, or fixed to the housing 1800. The contact assemblyframe assembly 140 defines a number of slots or channels (not shown).Each contact assembly slider member 142 is movably disposed in a slotand thereby movably coupled to the contact assembly frame assembly 140.Each contact assembly contact spring 144 is disposed between a contactassembly slider member 142 and a conductor member 126. Each contactassembly contact spring 144 is structured to, and does, bias theconductor member 126 away from the associated contact assembly slidermember 142. It is noted that the contact assembly contact springs 144have a sufficiently limited length so that each conductor member 126 isspaced from the associated contacts 124, 126 when in the first position.

In an exemplary embodiment, the contact assembly 120 also includes anelongated handle member 150. As show in FIGS. 25-26, the contactassembly handle member 150, or “handle member 150,” is a U-shaped body152 having a first and second tine 154, 156 and a bight 158 that extendslaterally across the contact assembly frame assembly 140. For thepurpose of discussing the toggle operating mechanism 2000, the handlemember 150 is considered to be a single elongated member correspondingto a tine 154. That is, as used herein, the handle tine 154 isidentified as the elongated “handle link 154” which has a first end 155and a second end 157. Second tine 156 has also has a first end 155′ anda second end 157′.

In an exemplary embodiment, shown in schematic FIGS. 27-29, the togglelinkage 2002 includes the upper link 2020, the lower link 2030, and thehandle link 154. The handle link second end 157 is rotatably coupled, orrotatably directly coupled, to the housing 1800. The upper link firstend 2022 is rotatably coupled, or rotatably directly coupled, to thehousing 1800. The upper link second end 2024 is rotatably coupled to thelower link first end 2032 forming the knee joint 2010, as discussedabove. Further, the lower link second end 2034 is rotatably coupled, orrotatably directly coupled, to the contact assembly slider member(s)142. In this embodiment, the toggle line 2006 generally corresponds to,i.e., is aligned with (or parallel to) the longitudinal axis of theupper link 2020. The handle link 154 moves between a first position,wherein the toggle linkage 2002 is in the first configuration, and asecond position, wherein the toggle linkage 2002 is in the secondconfiguration.

Further, in an exemplary embodiment, the toggle linkage 2002 includes anelongated spring 2050. The toggle linkage spring 2050 includes a firstend 2052 and a second end 2054. In this embodiment, the toggle linkageline of action 2004 extends between the toggle linkage spring first end2052 and the toggle linkage spring second end 2054. Further, the togglelinkage spring first end 2052 is coupled, directly coupled, rotatablycoupled, or fixed to the handle link first end 155. The toggle linkagespring second end 2054 is coupled, directly coupled, rotatably coupled,or fixed to the knee joint 2010. In this configuration, the toggleoperating mechanism 2000 is structured to move the contact assembly 120into both the first and second positions by a snap-action and solves theproblems stated above.

Further, the contact assembly 120, in an exemplary embodiment as shownin FIGS. 30-33, includes an actuating assembly 2100 structured to movethe toggle operating mechanism 2000 between the first and secondpositions. That is, the actuating assembly 2100 moves between a firstconfiguration, wherein the contact assembly 120 is in its firstposition, and a second configuration, wherein the contact assembly 120is in its second position. Further, as described below, when theactuating assembly 2100 is in the first configuration, the elementsthereof, with the exceptions noted below, are in their firstpositions/configurations as described below, and, when the assembly 2100is in the second configuration, the elements thereof, with theexceptions noted below, are in their second positions/configurations asdescribed below. As shown, one embodiment of the actuating assembly 2100includes a first (open/off) push button 2102, a second (close/on) pushbutton 2104, and a number of gears 2106 which, as shown in an exemplaryembodiment includes a first gear 2108, a second gear 2110 and a thirdgear 2112. Further, in this embodiment, the contact assembly 120includes a carrier housing 2130. The carrier housing 2130 is structuredto, and does, generally enclose the contact assembly frame assembly 140and the toggle linkage 2002. As shown in FIGS. 32-33, the carrierhousing 2130 also provide mountings 2132 suitable for the number ofgears 2106. The carrier housing 2130 is also coupled, directly coupled,removably coupled or fixed to the housing 1800.

In an exemplary embodiment, the actuating assembly first gear 2108 is acombination gear. As used herein, a “combination gear” is a gear thatincludes a plurality of different sets of teeth. As shown in FIG. 34,actuating assembly first gear 2108 includes a generally toroid body 2120having a first axial side 2122, a second axial side 2124, a radial innerside 2126, and a radial outer side 2128. As used herein, a “radialside/surface” for a circular or cylindrical body is a side/surface thatextends about, or encircles, the center thereof or a height line passingthrough the center thereof. As used herein, an “axial side/surface” fora circular or cylindrical body is a side that extends in a planeextending generally perpendicular to a height line passing through thecenter. That is, generally, for a cylindrical soup can, the “radialside/surface” is the generally circular sidewall and the “axialside(s)/surface(s)” are the top and bottom of the soup can.

The actuating assembly first gear first axial side 2122 includes bevelgear teeth 2123 which, in an exemplary embodiment, are angled outwardlyfrom the center of the actuating assembly first gear body 2120. Theactuating assembly first gear outer side 2128 includes spur gear teeth2129. In an exemplary embodiment which includes an interlock assembly2300, discussed below, the actuating assembly first gear second axialside 2124 also includes bevel gear teeth 2125. The various teeth 2123,2125, 2129 extend over one of an arc, or, over the circumference of theactuating assembly first gear body 2120. The actuating assembly firstgear inner side 2126 is generally smooth.

The actuating assembly first gear 2108 is rotatably coupled to thecarrier housing 2130 and generally extends about, i.e., encircling, thelongitudinal axis of the housing 1800. The carrier housing 2130, in anexemplary embodiment, includes a generally circular channel (not shown)that is a mounting 2132 for the actuating assembly first gear 2108.Thus, the actuating assembly first gear 2108 has an axis of rotation2109 that is generally aligned with, or parallel to, the longitudinalaxis of the housing 1800.

The actuating assembly second gear 2110 is, in an exemplary embodiment,also a combination gear. That is, the actuating assembly second gear2110 includes a generally circular toroidal body 2160 having an outerradial side 2162 and an inner radial side 2164. The actuating assemblysecond gear inner side 2164 defines a generally circular mountingcoupling. The actuating assembly second gear outer radial side 2162includes a first portion 2166 and a second portion 2168. In an exemplaryembodiment, each of the actuating assembly second gear outer radial sidefirst portion 2166 and the actuating assembly second gear outer radialside second portion 2168 extend about 180° over the actuating assemblysecond gear outer radial side 2162. The actuating assembly second gearouter radial side first portion 2166 includes a number of bevel gearteeth 2167, hereinafter “actuating assembly second gear bevel gear teeth2167,” that correspond to the actuating assembly first gear first axialside bevel gear teeth 2123. The actuating assembly second gear outerradial side second portion 2168 includes a number of spur gear teeth2169, hereinafter “actuating assembly second spur gear teeth 2169.”

The actuating assembly second gear 2110 is rotatably coupled to alateral side of the carrier housing 2130. That is, the carrier housing2130 includes a first axle lug 2134 that corresponds to the openingdefined by actuating assembly second gear inner side 2164. The carrierhousing first axle lug 2134 is positioned so that, when the actuatingassembly second gear 2110 is rotatably coupled thereto, the actuatingassembly second gear bevel gear teeth 2167 operatively engage, or areoperatively engaged by, the actuating assembly first gear first axialside bevel gear teeth 2123.

As shown in FIGS. 32-33, the actuating assembly third gear 2112, in anexemplary embodiment, is a spur gear. That is, the actuating assemblythird gear 2112 includes a generally circular toroidal body 2170 havingan outer radial side 2172 and an inner radial side 2174. The actuatingassembly second gear inner side 2174 defines a generally circularmounting coupling. The actuating assembly second gear outer radial side2172 includes a number of spur gear teeth 2176. The actuating assemblysecond gear body radial side spur gear teeth 2176 are structured tooperatively engage or be operatively engaged by, the actuating assemblysecond gear actuating assembly second spur gear teeth 2169. Theactuating assembly third gear 2112 is further structured to be, and is,coupled, directly coupled, or fixed to the handle member 150 and, in anexemplary embodiment, to the handle link 154. Further, in an exemplaryembodiment, the actuating assembly third gear 2112 is fixed to thehandle link 154. In this configuration, movement of the actuatingassembly third gear 2112 is transferred to the handle link 154. That is,the actuating assembly third gear 2112 is operatively coupled the handlelink 154.

In an exemplary embodiment and as noted above, the actuating assemblyfirst and second push buttons 2102, 2104 are substantially similar andonly the second push button 2102 will be described. Thereafter, anydescription of the first push button 2104 will use the same referencenumbers followed by a single prime (′) indication. The second pushbutton 2104 includes an elongated body 2200″ having a first end 2202″and a second end 2204″. As shown in FIG. 32, the first push button bodyfirst end 2202″, in an exemplary embodiment, includes an enlargedportion 2206′, i.e., a portion with a cross-section that is larger thanthe other portions of the first push button body 2202′. The first pushbutton body second end 2204′ includes a rack 2208′. The first pushbutton body rack 2208′ includes a number of teeth 2210′ that arestructured to operatively engage, or be engaged by, the actuatingassembly first gear 2108 and, in an exemplary embodiment, the actuatingassembly first gear outer side spur gear teeth 2129.

The housing 1800 includes two push button openings 1810, 1812 sized tocorrespond to the first and second push button bodies 2200′, 2200″. Thatis, the two push button openings 1810, 1812 have a cross-sectional sizeand shape that generally corresponds to the first and second push buttonbodies 2200′, 2200″. The two push button openings 1810, 1812 arepositioned on the housing 1800 so that, when the actuating assembly 2100is installed in the housing 1800, the first and second push buttonbodies 2200′, 2200″ are disposed adjacent to, and operatively engage,generally opposing sides of the actuating assembly first gear 2108. Thatis, the first and second push button body teeth 2210′, 2210″ operativelyengage opposing sides of the actuating assembly first gear 2108.

The first and second push buttons 2102, 2104 are collectively structuredto move between a first configuration, wherein each conductor member 126is in a first position and a second configuration, wherein eachconductor member 126 is in a second position. Individually, the firstand second push buttons 2102, 2104 are structured to move between anextended position, wherein one of the first and second push buttonbodies 2200′, 2200″ is extended relative to the housing 1800, and, asecond position wherein one of the first and second push button bodies2200′, 2200″ is retracted relative to the housing 1800. It is understoodthat, in an exemplary embodiment, the positions of the first and secondpush button bodies 2200′, 2200″ are opposite each other. That is, whenthe first push button body 2200′ is in the first position, the secondpush button body 2200″ is in the second position, and, when the firstpush button body 2200′ is in the second position, the second push buttonbody 2200″ is in the first position.

Thus, as used herein, when the first and second push buttons 2102, 2104are in the “first configuration,” the first push button 2102, i.e., thefirst push button body 2200′, is in the retracted, second position andthe second push button 2104, i.e., second push button body 2200″, is inthe extended, first position. That is, colloquially, the second pushbutton body 2200″ is sticking up, and, the first push button body 2200′is pushed down. When the first and second push buttons 2102, 2104 are inthe “first configuration,” each conductor member 126 is in the first(open) position. Conversely, as used herein, when the first and secondpush buttons 2102, 2104 are in the “second configuration,” the firstpush button 2102, i.e., the first push button body 2200′, is inextended, first position, and, the second push button 2104, i.e., secondpush button body 2200″, is in retracted, second position. That is,colloquially, the second push button body 2200″ is pushed down and thefirst push button body 2200′ is sticking up. When the first and secondpush buttons 2102, 2104 are in the “second configuration,” eachconductor member 126 is in the second (closed) position.

In this configuration, the actuating assembly 2100 operates as follows.Assuming the contact assembly 120 is in the first configuration, thetoggle linkage 2002 is in the first configuration, the handle link 154is in its first position, and the first and second push buttons 2102,2104 are in first configuration. Thus, the second push button 2104 issticking up. When the second push button 2104 is pushed down to thesecond position, i.e., toward the housing 1800, the second push buttonbody 2200″ moves into/toward the housing 1800. As stated above, thesecond push button body rack 2208″ operatively engages the actuatingassembly first gear 2108 causing the actuating assembly first gear 2108to rotate. Rotation of the actuating assembly first gear 2108 has twoeffects; first, the actuating assembly first gear 2108 operativelyengages the first push button 2102 causing the first push button body2200′ to move to the first position. Second, the actuating assemblyfirst gear first axial side bevel gear teeth 2123 operatively engage theactuating assembly second gear bevel gear teeth 2167; this causes theactuating assembly second gear 2110 to rotate. As noted above, theactuating assembly second spur gear teeth 2169 operatively engage theactuating assembly third gear 2112; thus, rotation of the actuatingassembly second gear 2110 causes the actuating assembly third gear 2112to rotate. Further, as stated above, the actuating assembly third gear2112 is, in an exemplary embodiment, fixed to the handle link 154. Thus,rotation of the actuating assembly third gear 2112 causes the handlelink 154 to move from the first position to its second position.Further, as noted above, when the handle link 154 moves from the firstposition to its second position, the toggle linkage 2002 moves from itsfirst configuration to its second configuration. Further, as statedabove, when the toggle linkage 2002 moves from its first configurationto its second configuration, the conductor members 126 move to theirsecond positions. Moreover, as stated above, the toggle operatingmechanism 2000 is a snap-action mechanism that is structured to open andclose the contact assembly 120 by a snap-action. Thus, when the secondpush button 2104 is actuated, i.e., pushed down, the contact assembly120 moves into the second position by a snap-action.

At this point, the elements and assemblies are in the secondconfiguration/positions, with the exception of the first push button2102, i.e., the first push button body 2200′, which is in its firstposition; that is, the first push button 2102 is sticking up.Hereinafter, it is understood that the first push button 2102, i.e., thefirst push button body 2200′, is in its “first” position when the otherelements identified above are in their “second” position/configurationand vice-versa; this is an exception to the general convention thatelements are in the same position/configuration at the same time. Whenthe first push button 2102 is moved to the second position, i.e., towardthe housing 1800, the first push button body 2200′ moves into/toward thehousing 1800. As stated above, the first push button body rack 2208′operatively engages the actuating assembly first gear 2108 causing theactuating assembly first gear 2108 to rotate. Rotation of the actuatingassembly first gear 2108 has two effects; first, the actuating assemblyfirst gear 2108 operatively engages the second push button 2104 causingthe second push button body 2200″ to move to the first position. Second,the actuating assembly first gear first axial side bevel gear teeth 2123operatively engage the actuating assembly second gear bevel gear teeth2167; this causes the actuating assembly second gear 2110 to rotate. Asnoted above, the actuating assembly second spur gear teeth 2169operatively engage the actuating assembly third gear 2112; thus,rotation of the actuating assembly second gear 2110 causes the actuatingassembly third gear 2112 to rotate. Further, as stated above, theactuating assembly third gear 2112 is, in an exemplary embodiment, fixedto the handle link 154. Thus, rotation of the actuating assembly thirdgear 2112 causes the handle link 154 to move from the second position toits first position. Further, as noted above, when the handle link 154moves from the second position to its first position, the toggle linkage2002 moves from its second configuration to its first configuration.Further, as stated above, when the toggle linkage 2002 moves from itssecond configuration to its first configuration, the conductor members126 move to their first positions. Moreover, as stated above, the toggleoperating mechanism 2000 is a snap-action mechanism that is structuredto open and close the contact assembly 120 by a snap-action. Thus, whenthe first push button 2102 is actuated, i.e., pushed down, the contactassembly 120 moves into the first positions by a snap-action.

Further, as noted above and as shown in FIGS. 24, 30, 33, 35-37, thepower connector 100 includes an interlock, hereinafter identified as theinterlock assembly 2300, that prevents engagement and disengagement ofthe pins 164,166,168 and the sleeves 114,116,118 when the contactassembly 120 is in the second position. That is, the interlock assembly2300 is structured to, and does, prevent the first and second housings1802, 1804 from being coupled or decoupled when the contact assembly 120is in the second position. It is understood that elements of theinterlock assembly 2300 are disposed on each of the first and secondhousings 1802, 1804 and cooperate with each other. Further, as describedabove, it is understood that the contact assembly 120 may be disposed ineither of the first and second housings 1802, 1804 and that the elementsof the interlock assembly 2300 that are coupled to the elements ofcontact assembly 120, or in an exemplary embodiment the toggle operatingmechanism 2000, are in the same housing 1800 as the contact assembly120. In the following exemplary embodiment, the contact assembly 120 isshown to be in the first housing 1802. Thus, it is understood that ifthe contact assembly 120 were in the second housing 1804, the elementsof the interlock assembly 2300 that are described below as being in thefirst housing 1802 would, instead, be in the second housing 1804.

Generally, the first and second housings 1802, 1804 move between aseparated, first configuration (FIG. 24), wherein the first and secondhousings 1802, 1804 are separated, and a coupled, second configuration(FIG. 36), wherein the first and second housings 1802, 1804 are coupledor directly coupled. Further, the first and second housings 1802, 1804move between a first transition configuration (FIG. 35), wherein thepower connector first housing 1802 and the power connector secondhousing 1804 are moving from the first configuration to the secondconfiguration, and a second transition configuration, wherein the powerconnector first housing 1802 and the power connector second housing 1804move from the second configuration to the first configuration. That is,generally, the “first transition configuration” is when the first andsecond housings 1802, 1804 are being coupled together, and, the “secondtransition configuration” is when the first and second housings 1802,1804 are being separated.

The interlock assembly 2300 includes elements that are movable so as tobe in an “obstructing position” relative to another element. That is, asset forth below, elements of the interlock assembly 2300 move andtherefore have a “path of travel” (or a “path”). As used herein, a firstelement is in an “obstructing position” relative to a second elementwhen the first element is disposed in the path of a second element.Moreover, the interlock assembly 2300 is structured to, and does,maintain the conductor members 126, as well as the other assembliesidentified above, in the first position (or configuration) when thefirst and second housings 1802, 1804 are in the separated, firstconfiguration. Further, the interlock assembly 2300 is structured toonly allow the conductor members 126, as well as the other assembliesidentified above, to move to their second position (or configuration)when the first and second housings 1802, 1804 are in the coupled, secondconfiguration.

As described more frilly below, the interlock assembly locking member2310 is movably coupled, and in an exemplary embodiment rotatablycoupled, to the first housing 1802. The interlock assembly lockingmember 2310 is movable between a first position, wherein the interlockassembly locking member 2310 generally maintains the various elementsand assemblies identified above in the first position/configuration, anda second position, wherein the various elements and assembliesidentified above are structured to be moved into the secondposition/configuration. Thus, when the first and second housings 1802,1804 are in the separated, first configuration, the interlock assembly2300 is structured to maintain the conductor members 126, as well as theother assemblies identified above, in the first position (orconfiguration). When the first and second housings 1802, 1804 are in thecoupled, second configuration, the interlock assembly 2300 is structuredto allow the conductor members 126, as well as the other assembliesidentified above, to be moved to the second position (or configuration).

Further, the interlock assembly 2300 is structured to, and does,maintain the first and second housings 1802, 1804 in the secondconfiguration when the conductor members 126, as well as the otherassemblies identified above, are in the second position (orconfiguration). The conductor members 126, as well as the otherassemblies identified above, must be moved to their first position (orconfiguration) for the first and second housings 1802, 1804 to beseparated, i.e., returned to the separated, first position. Thus,generally, the interlock assembly 2300 is structured to, and does,maintain the conductor members 126, as well as the other assembliesidentified above, in their first position (or configuration) when thefirst and second housings 1802, 1804 are separated, and, the interlockassembly 2300 is structured to, and does, maintain the first and secondhousings 1802, 1804 in the coupled, second configuration when theconductor members 126, as well as the other assemblies identified above,are in their second position (or configuration).

Further, if the conductor members 126, as well as the other assembliesidentified above, are in the second position (or configuration) whilethe first and second housings 1802, 1804 are in the separated, firstconfiguration, the interlock assembly 2300 is structured to, and does,prevent the first and second housings 1802, 1804 from being coupled,i.e., moved in to the second configuration. In an exemplary embodiment,the interlock assembly 2300 includes a locking member 2310, an interlockassembly latching member assembly 2350, and an interlock assemblyactuator member 2390. As shown in FIG. 37, the interlock assemblylocking member 2310 includes a first locking surface 2312, a secondlocking surface 2313, and a third locking surface 2314. In an exemplaryembodiment, the interlock assembly locking member 2310 includes atorus-shaped body 2315 having a first axial surface 2316, a radial innersurface 2318, a radial outer surface 2320, and a second axial surface2322. The interlock assembly locking member body first axial surface2316 defines a number of cavities 2324, hereinafter “interlock assemblylocking member body number of cavities” 2324. As shown, and in anexemplary embodiment, the interlock assembly locking member body numberof cavities 2324 includes two generally opposed interlock assemblylocking member body number of cavities 2324, i.e., cavities disposedabout 180° apart. In an exemplary embodiment, the interlock assemblylocking member first locking surface 2312 is disposed on the interlockassembly locking member body number of cavities 2324. As used herein,and when used in relation to a locking surface or latching surface,“disposed on” means that the surface is part of, or defines part of, theidentified element. Thus, in this exemplary embodiment, the interlockassembly locking member first locking surface 2312 defines part of theinterlock assembly locking member body number of cavities 2324.

In an exemplary embodiment, the interlock assembly locking member bodyinner surface 2318 defines the interlock assembly locking member secondlocking surface 2313. Stated alternately, the interlock assembly lockingmember second locking surface 2313 is disposed on the interlock assemblylocking member body inner surface 2318. The interlock assembly lockingmember body outer surface 2320 defines the interlock assembly lockingmember third locking surface 2314. Stated alternately, the interlockassembly locking member third locking surface 2314 is disposed on theinterlock assembly locking member body outer surface 2320.

In an exemplary embodiment, the interlock assembly locking member body2315 also includes an upper portion 2326 and a lower portion 2328. Asshown, the interlock assembly locking member body upper portion 2326defines an elongated, radial passage 2330 between the interlock assemblylocking member body outer surface 2320 and the interlock assemblylocking member body inner surface 2318; hereinafter “the interlockassembly locking member body passage” 2330. Further, the interlockassembly locking member body upper portion 2326 defines the interlockassembly locking member second locking surface 2313 and the interlockassembly locking member third locking surface 2314. The interlockassembly locking member body lower portion 2328 is, in an exemplaryembodiment, a complete torus.

Further, the interlock assembly locking member body second axial surface2322, and/or the interlock assembly locking member body radial outersurface 2320, includes a number of gear teeth 2344. As shown, and in anexemplary embodiment, the interlock assembly locking member body secondaxial surface gear teeth 2344, hereinafter “interlock assembly lockingmember body gear teeth” 2344, are bevel gear teeth. As noted above, inan embodiment with an interlock assembly 2300, the actuating assemblyfirst gear second axial side 2124 also includes bevel gear teeth 2125.The interlock assembly locking member body gear teeth 2344 correspondto, and are structured to operatively engage, or be operatively engagedby, the actuating assembly first gear second axial side bevel gear teeth2125.

The interlock assembly locking member 2310 is movably coupled, and in anexemplary embodiment rotatably coupled, to the first housing 1802. Theinterlock assembly locking member 2310 is movable between a firstposition wherein the interlock assembly locking member first lockingsurface 2312 is in a first position, the interlock assembly lockingmember second locking surface 2313 is in a first position and theinterlock assembly locking member third locking surface 2314 is in afirst position, and, a second position wherein the interlock assemblylocking member first locking surface 2312 is in a second position, andthe interlock assembly locking member second locking surface 2313 is ina second position, the interlock assembly locking member third lockingsurface 2314 is in a second position. The interactions of the interlockassembly locking member 2310 with the interlock assembly latching memberassembly 2350 and the interlock assembly actuator member 2390 aredescribed below.

The interlock assembly latching member assembly 2350 includes aninterlock assembly latching member 2352, hereinafter the “interlockassembly latching member” 2352, and a biasing device 2354. The interlockassembly latching member 2352 includes a first latching surface 2356. Inan exemplary embodiment, the interlock assembly latching member 2352includes a body 2360 with a base member 2362, an angled engagementsurface 2364 and a number of protrusions 2366. The interlock assemblylatching member base member 2362 is, in an exemplary embodiment, agenerally planar member including an upper surface 2370 and a lowersurface 2372. The interlock assembly latching member angled engagementsurface 2364 is disposed on a lug 2374 that protrudes from the interlockassembly latching member base member upper surface 2370. Similarly, theinterlock assembly latching member number of protrusions 2366 alsoprotrude from the interlock assembly latching member base member uppersurface 2370. Each of the interlock assembly latching number ofprotrusions 2366 is sized and shaped to correspond to one of theinterlock assembly locking member body number of cavities 2324. Thus, inan exemplary embodiment, there are two elongated interlock assemblylatching protrusions 2366 wherein the longitudinal axis of the interlockassembly latching protrusions 2366 are generally aligned. The interlockassembly latching member first latching surface 2356 is disposed on theinterlock assembly latching number of protrusions 2366. Further, in anexemplary embodiment, the interlock assembly latching member body 2360includes a number of guides or, as used herein, “bumpers” 2380. Theinterlock assembly latching member body bumpers 2380 protrude from theinterlock assembly latching member base member upper surface 2370 andeach has a lower surface 2372 shaped to generally correspond to theinterlock assembly locking member body inner surface 2318.

The interlock assembly latching member 2352 is movably coupled to thefirst housing 1802. The interlock assembly latching member 2352 ismovable between a first position, wherein the interlock assemblylatching member first latching surface 2356 is in a first position, anda second position, wherein the interlock assembly latching member firstlatching surface 2356 is in a second position. In an exemplaryembodiment, the interlock assembly latching member assembly biasingdevice 2354 is a spring 2378 disposed between the interlock assemblylatching member 2352 and the power connector first housing 1802. Theinterlock assembly latching member assembly biasing device 2354 biasesthe interlock assembly latching member 2352 to the first position. Theinteractions of the interlock assembly latching member assembly 2350with the interlock assembly locking member 2310 and the interlockassembly actuator member 2390 are described below.

The interlock assembly actuator member 2390 (FIGS. 24, 35, 36), in anexemplary embodiment, is a body 2392 that is coupled, directly coupled,or fixed to the second housing 1804. Further, in an exemplaryembodiment, the interlock assembly actuator member 2390 is unitary withthe second housing 1804. That is, as used herein, “unitary” elements arealso said to be coupled, directly coupled, or fixed to each other. In anexemplary embodiment, the interlock assembly actuator member 2390 is aprotrusion extending generally radially from a generally circular secondhousing 1804. The leading edge 2394 of the interlock assembly actuatormember 2390 is tapered. As used herein, a “leading edge” or a “trailingedge” is a surface rather than an intersection of a number of surfaces.That is, as used herein, the “interlock assembly actuator member leadingedge 2394” is that surface that is closest to the first housing 1802 asthe first and second housing 1802, 1804 move from the first position tothe second position. The trailing edge 2396 of the interlock assemblyactuator member 2390 is a generally axial surface relative to the secondhousing 1804. The interlock assembly actuator member 2390 includes asecond latching surface 2400; in an exemplary embodiment, the interlockassembly actuator member trailing edge 2396 is the interlock assemblyactuator member second latching surface 2400.

The interlock assembly actuator member 2390 is movable between a firstposition, wherein the interlock assembly actuator member 2390 is spacedfrom interlock assembly latching member 2352, and a second position,wherein the interlock assembly actuator member 2390 operatively engagesthe interlock assembly latching member 2352. The interlock assemblyactuator member 2390 first and second positions correspond to the firstand second housings 1802, 1804 first and second positions. Further, theinterlock assembly actuator member 2390 also moves between a firsttransition position, wherein the interlock assembly actuator member 2390moves from the first position to the second position and wherein theinterlock assembly actuator member 2390 operatively engages theinterlock assembly latching member 2352 and moves the interlock assemblylatching member 2352 from its first position to its second position,and, a second transition position, wherein the interlock assemblyactuator member 2390 moves from its second position to its firstposition and wherein the interlock assembly actuator member 2390disengages the interlock assembly latching member 2352 and moves theinterlock assembly latching member 2352 from its second position to itsfirst position. It is noted that the interlock assembly actuator member2390 first transition position corresponds to the power connector firsthousing 1802 and the power connector second housing 1804 firsttransition configuration, and, the interlock assembly actuator member2390 second transition position corresponds to the power connector firsthousing 1802 and the power connector second housing 1804 secondtransition configuration.

In an exemplary embodiment, the interlock assembly 2300 is assembled asfollows. The interlock assembly locking member 2310 is rotatably coupledto the first housing 1802 with the interlock assembly locking memberbody first axial side 2316 disposed facing, and immediately adjacent,the interlock assembly latching member assembly 2350. The interlockassembly latching member 2352 is movably coupled to the first housing1802 and transitions, i.e., moves without changing orientation, relativeto the first housing 1802. Further, the actuating assembly first gearsecond axial side gear teeth 2125 are coupled to, and when movedoperatively coupled to, the interlock assembly locking member body gearteeth 2344. As noted above, when the first and second push buttons 2102,2104 are moved, the actuating assembly first gear 2108 rotates. Thus,the first and second push buttons 2102, 2104 are operatively coupled tothe interlock assembly locking member 2310. It is understood that themotion of the actuating assembly first gear 2108 drives the motion ofthe interlock assembly 2300.

When the first and second housings 1802, 1804 are in the firstconfiguration, i.e., separated, the contact assembly 120 is in the firstconfiguration, the toggle linkage 2002 is in the first configuration,the handle link 154 is in its first position, and the first and secondpush buttons 2102, 2104 are in first configuration. Further, theinterlock assembly 2300 is assembled so that when the first and secondhousings 1802, 1804 are in the first configuration, i.e., separated, thevarious elements of the interlock assembly 2300 are in their firstpositions or configurations. Thus, the locking member 2310 is in itsfirst position with the interlock assembly locking member first lockingsurface 2312 is in a first position and the interlock assembly lockingmember second locking surface 2313 is in a first position. In anexemplary embodiment, when the interlock assembly locking member secondlocking surface 2313 is in a first position, the interlock assemblylocking member body passage 2330 faces outwardly from the first housing1802. That is, longitudinal axis of the interlock assembly lockingmember body passage 2330 is generally aligned with the path of travel ofthe second housing 1804 and the path of travel of the interlock assemblyactuator member 2390. Thus, the interlock assembly actuator member 2390is able to pass through the interlock assembly locking member bodypassage 2330.

Further, the interlock assembly latching member 2352 is in its firstposition (and is biased to that position by the interlock assemblylatching member assembly biasing device 2354). When the interlockassembly latching member 2352 is in its first position, the interlockassembly latching member number of protrusions 2366 are disposed in theinterlock assembly locking member body number of cavities 2324. Thus,the interlock assembly latching member first latching surface 2356 isdisposed in an obstructing position relative to the interlock assemblylocking member second locking surface 2313. In this configuration, theinterlock assembly locking member body 2315 cannot rotate. If theinterlock assembly locking member body 2315 cannot rotate, all elementsoperatively coupled thereto also cannot rotate; thus, the elements ofthe interlock assembly 2300 as well as the contact assembly 120 and theactuating assembly 2100 are in, and are maintained in, their respectivefirst positions/configurations.

Further, at this point it is noted that, if the first and secondhousings 1802, 1804 are in the first configuration, i.e., separated, andthe contact assembly 120 is in the second configuration, the interlockassembly 2300 is structured to, and does, prevent the first and secondhousings 1802, 1804 from being coupled, i.e., moved in to the secondconfiguration. That is, if the second push button 2104 is pushed down tothe second position while overcoming the lock of the interlock assemblylocking member body 2315, (colloquially, if the conductor members 126and other assemblies noted above, are forced into the closed, secondposition/configuration while the first and second housings 1802, 1804are separated) the actuating assembly first gear 2108 rotates therebymoving the locking member 2310 to its second position with the interlockassembly locking member first locking surface 2312 in a second position,the interlock assembly locking member second locking surface 2313 is ina second position, and the interlock assembly locking member thirdlocking surface 2314 disposed in a second position. That is, theinterlock assembly locking member body passage 2330 is rotated so thatit does not face the second housing 1804. Thus, in this position, theinterlock assembly locking member third locking surface 2314 is disposedin an obstructing position relative to the interlock assembly actuatormember 2390. When the interlock assembly actuator member 2390 cannotpass through the interlock assembly locking member body passage 2330,the first and second housings 1802, 1804 cannot be moved into theirsecond configuration. That is, the interlock assembly 2300 prevents thecoupling of the first and second housings 1802, 1804 when the contactassembly is in the second configuration.

The interlock assembly 2300 elements interact with each other asfollows. Again, when the first and second housings 1802, 1804 are in thefirst configuration, i.e., separated, the contact assembly 120 is in thefirst configuration, the toggle linkage 2002 is in the firstconfiguration, the handle link 154 is in its first position, and thefirst and second push buttons 2102, 2104 are in first configuration.Further, as noted above, the interlock assembly 2300 is assembled sothat when the first and second housings 1802, 1804 are in the firstconfiguration, i.e., separated, the various elements of the interlockassembly 2300 are in their first positions or configurations. Thus, asdescribed above, the interlock assembly actuator member 2390 is able topass through the interlock assembly locking member body passage 2330.Accordingly, when the interlock assembly actuator member 2390 is movinginto the second position, i.e., when the interlock assembly actuatormember 2390 is in the first transition position, the interlock assemblyactuator member 2390 passes through the interlock assembly lockingmember body passage 2330 and the interlock assembly actuator member 2390operatively engages the interlock assembly latching member 2352 andmoves the interlock assembly latching member 2352 from its firstposition to its second position. That is, in an exemplary embodiment,the interlock assembly actuator member leading edge 2394 engages theinterlock assembly latching member angled engagement surface 2364. Thisengagement causes the interlock assembly latching member 2352 to move toits second position. When the interlock assembly latching member 2352 isin its second position, the interlock assembly latching member number ofprotrusions 2366 are not disposed in the interlock assembly lockingmember body number of cavities 2324. Thus, the interlock assemblylatching member first latching surface 2356 is not disposed in anobstructing position relative to the interlock assembly locking membersecond locking surface 2313. In this configuration, the interlockassembly locking member body 2315 can rotate. Moreover, when theinterlock assembly actuator member 2390 completes the first transitionposition, the first and second housings 1802, 1804 are in their secondconfiguration, i.e., the first and second housings 1802, 1804 arecoupled.

At this point, the actuating assembly 2100 is moved from the firstconfiguration to the second configuration. That is, as described above,the second push button 2104 is pushed down to the second position which,among other actions, causes the actuating assembly first gear 2108 torotate. The actuating assembly first gear 2108 is operatively coupled tothe interlock assembly locking member 2310 and causes the interlockassembly locking member 2310 to move to its second position wherein theinterlock assembly locking member first locking surface 2312 is in asecond position, the interlock assembly locking member second lockingsurface 2313 is in a second position, and the interlock assembly lockingmember third locking surface 2314 is in a second position. As notedabove, in this position the interlock assembly locking member bodypassage 2330 is rotated so that it does not face the second housing1804. Thus, in this position, the interlock assembly locking membersecond locking surface 2313 is disposed in an obstructing positionrelative to the interlock assembly actuator member 2390. That is, in anexemplary embodiment, the interlock assembly locking member secondlocking surface 2313 is disposed in an obstructing position relative tointerlock assembly actuator member second latching surface 2400. Thus,the interlock assembly actuator member 2390, and therefore the secondhousing 1804, cannot be moved to the first position/configuration, i.e.,separated, while the contact assembly 120 is in the second position.

When the first push button 2102 is moved to the second position, asdescribed above, generally the reverse motions occur. That is, theactuating assembly first gear 2108 rotates and operatively engages theinterlock assembly locking member 2310 and causes the interlock assemblylocking member 2310 to move to its first position wherein the interlockassembly locking member first locking surface 2312 is in a firstposition, the interlock assembly locking member second locking surface2313 is in a first position, and the interlock assembly locking memberthird locking surface 2314 is in a first position. When the interlockassembly locking member 2310 is in the first position, the interlockassembly latching member assembly biasing device 2354 biases theinterlock assembly latching member 2352 to the first position asdescribed above. Further, when the interlock assembly locking member2310 is in the first position, the interlock assembly locking membersecond locking surface 2313 is in a first position and the interlockassembly locking member body passage 2330 faces outwardly from the firsthousing 1802. That is, the interlock assembly locking member secondlocking surface 2313 is no longer in an obstructing position relative tothe interlock assembly actuator member 2390. Thus, the obstructingposition relative to the interlock assembly actuator member 2390, aswell as the second housing 1804 can be, and are, moved to their firstposition/configuration; that is, the first and second housings 1802,1804 are separated. Thus, the interlock assembly 2300 solves theproblems stated above.

Further, or alternately, the interlock assembly 2300 provides aconfiguration of elements wherein, when the interlock assembly actuatormember is in the first position, the interlock assembly latching memberis in the first position, and the interlock assembly locking member isin the first position. Further, when the interlock assembly latchingmember 2352 is in the first position the interlock assembly latchingmember first latching surface 2356 is disposed in an obstructingposition relative to the interlock assembly locking member first lockingsurface, wherein the interlock assembly locking member 2310 ismaintained in the first position. Further, when the interlock assemblylocking member 2310 is in the first position, the interlock assemblylocking member second locking surface 2313 is not in an obstructingposition relative to the interlock assembly actuator member 2352.Further, when the interlock assembly latching member 2352 is in thesecond position, the interlock assembly latching member first latchingsurface 2356 is not disposed in an obstructing position relative to theinterlock assembly locking member first locking surface 2312, whereinthe interlock assembly locking member 2310 is movable to the secondposition. Further, when the interlock assembly locking member 2310 is inthe second position, the interlock assembly locking member secondlocking surface 2313 is in an obstructing position relative to theinterlock assembly actuator member second latching surface 2400, whereinthe interlock assembly actuator member 2352 is maintained in the secondposition.

Further, when the interlock assembly actuator member 2390 moves betweena first transition position, wherein the interlock assembly actuatormember 2390 moves from its first position to its second position andwherein the interlock assembly actuator member 2390 operatively engagesthe interlock assembly latching member 2352 and moves the interlockassembly latching member 2352 from its first position to its secondposition, and, a second transition position, wherein the interlockassembly actuator 2390 member moves from its second position to itsfirst position and wherein the interlock assembly actuator member 2352disengages the interlock assembly latching member 2352 and moves theinterlock assembly latching member from its second position to its firstposition, and, wherein the interlock assembly actuator member firsttransition position corresponds to the power connector first housing1802 and the power connector second housing 1804 first transitionconfiguration, and, the interlock assembly actuator member secondtransition position corresponds to the power connector first housing1802 and the power connector second housing 1804 second transitionconfiguration.

While specific embodiments of the disclosed concept have been describedin detail, it will be appreciated by those skilled in the art thatvarious modifications and alternatives to those details could bedeveloped in light of the overall teachings of the disclosure. Forexample, while specific types of gear teeth are identified above, it isunderstood that any type of gear teeth may be used, so long as theidentified gears operatively engage the elements identified.Accordingly, the particular arrangements disclosed are meant to beillustrative only and not limiting as to the scope of the disclosedconcept which is to be given the full breadth of the claims appended andany and all equivalents thereof.

What is claimed is:
 1. An electrical connection element for a powerconnector, said power connector comprising an electrical component, saidelectrical connection element comprising: a housing; a contact assemblyenclosed by said housing and being electrically connected to a number ofsecond electrical mating members; a toggle operating mechanismstructured to open and close said contact assembly; wherein said contactassembly is structured to electrically connect and disconnect powerwhile a number of first electrical mating members remain mechanicallycoupled to said number of second electrical mating members; said toggleoperating mechanism includes a toggle linkage, said toggle linkagedefining a line of action and a toggle line; said toggle linkageoperatively coupled to said contact assembly; said toggle linkagemovable between a first configuration, wherein said contact assembly isopen, and a second configuration wherein said contact assembly isclosed; and wherein when said toggle linkage line of action is on afirst side of said toggle line, said toggle linkage is biased towardsaid toggle linkage first configuration, when said toggle linkage lineof action is on a second side of said toggle line, said toggle linkageis biased toward said toggle linkage second configuration, and when saidtoggle linkage line of action moves from one side of said toggle line ina direction to be aligned with said toggle line, said toggle linkageline of action continues to move in the same direction until said togglelinkage line of action is on the other side of said toggle line.
 2. Theelectrical connection element of claim 1 wherein: said toggle linkageincludes a knee joint having an axis of rotation; and said toggle lineextending through said knee joint axis of rotation.
 3. The electricalconnection element of claim 1 wherein: said toggle linkage includes anelongated spring; said toggle linkage spring including a first end and asecond end; and wherein said toggle linkage line of action extendsbetween said toggle linkage spring first end and said toggle linkagespring second end.
 4. The electrical connection element of claim 1wherein: said toggle linkage includes an elongated handle link, anelongated upper link, an elongated lower link, and an elongated spring;said handle link including a first end and a second end; said upper linkincluding a first end and a second end; said lower link including afirst end and a second end; said toggle linkage spring including a firstend and a second end; said handle link second end rotatably coupled tosaid housing; said upper link first end rotatably coupled to saidhousing; said upper link second end rotatably coupled to said lower linkfirst end defining a knee joint; said lower link second end rotatablycoupled to contact assembly; said toggle linkage spring first endcoupled to said handle link first end; said toggle linkage spring secondend coupled to said knee joint.
 5. A power connector comprising: anelectrical component having a number of first electrical mating members;and an electrical connection element comprising: a housing including anumber of second electrical mating members electrically connected tosaid number of first electrical mating members, a contact assemblyenclosed by said housing and being electrically connected to said numberof second electrical mating members; a toggle operating mechanism foropening and closing said contact assembly; and wherein said contactassembly is structured to electrically connect and disconnect powerwhile said number of first electrical mating members remain mechanicallycoupled to said number of second electrical mating members; said toggleoperating mechanism including a toggle linkage, said toggle linkagedefining a line of action and a toggle line; said toggle linkageoperatively coupled to said contact assembly; said toggle linkagemovable between a first configuration, wherein said contact assembly isopen, and a second configuration wherein, said contact assembly isclosed; and wherein when said toggle linkage line of action is on afirst side of said toggle line, said toggle linkage is biased towardsaid toggle linkage first configuration, when said toggle linkage lineof action is on a second side of said toggle line, said toggle linkageis biased toward said toggle linkage second configuration, and when saidtoggle linkage line of action moves in a direction to a position alignedwith said toggle line, said toggle linkage line of action continues tomove in the same direction until said toggle linkage line of action ison one of said first side of said toggle line or said second side ofsaid toggle line.
 6. The power connector of claim 5 wherein: said togglelinkage includes an elongated handle link, an elongated upper link, anelongated lower link, and an elongated spring; said handle linkincluding a first end and a second end; said upper link including afirst end and a second end; said lower link including a first end and asecond end; said toggle linkage spring including a first end and asecond end; said handle link second end rotatably coupled to saidhousing; said upper link first end rotatably coupled to said housing;said upper link second end rotatably coupled to said lower link firstend defining a knee joint; said lower link second end rotatably coupledto contact assembly; said toggle linkage spring first end coupled tosaid handle link first end; and said toggle linkage spring second endcoupled to said knee joint.
 7. An interlock assembly for a powerconnector, said power connector including a contact assembly, a firsthousing and a second housing, said contact assembly including a numberof line-side contacts, a number of load-side contacts, and a number ofmovable conductor members, each conductor member associated with oneline-side contact and one load-side contact, each said conductor membermovable between a first position, wherein said associated line-sidecontact and said associated load-side contact are not electricallyconnected, and a second position, wherein said associated line-sidecontact and said associated load-side contact are electricallyconnected, said power connector first housing and said power connectorsecond housing movable between a first configuration, wherein said powerconnector first housing and said power connector second housing areseparated, and a second configuration, wherein said power connectorfirst housing and said power connector second housing are coupled, saidpower connector first housing defining a partially enclosed space, saidpower connector second housing defining a partially enclosed space, saidpower connector first housing including an actuator assembly, saidactuator assembly including a first gear, said actuator assembly firstgear operatively coupled to said contact assembly, said first gearmovable between a first position, wherein each said conductor member isin the first position, and a second position, wherein each saidconductor member is in the second position, said interlock assemblycomprising: an interlock assembly locking member, said an interlockassembly locking member movably coupled to said power connector firsthousing, said interlock assembly locking member movable between a firstposition and a second position; an interlock assembly latching memberassembly, said interlock assembly latching member assembly including aninterlock assembly latching member, said interlock assembly latchingmember movably coupled to said power connector first housing, saidinterlock assembly latching member movable between a first position anda second position; an interlock assembly actuator member, said interlockassembly actuator member coupled to said second housing, said interlockassembly actuator member movable between a first position and a secondposition; wherein, when said power connector first housing and saidpower connector second housing are in said first configuration, and,when said movable conductor members are in said first configuration,said interlock assembly locking member is structured to maintain saidconductor members in said first position; wherein when said powerconnector first housing and said power connector second housing are insaid second configuration, and, when said movable conductor members arein said second configuration, said interlock assembly locking member isstructured to maintain said power connector first housing and said powerconnector second housing in said second position.
 8. The interlockassembly of claim 7 wherein when said interlock assembly latching memberis in said first position, and, when said interlock assembly lockingmember is in said first position, said interlock assembly latchingmember is disposed in an obstructing position relative to said interlockassembly locking member.
 9. The interlock assembly of claim 7 whereinwhen said interlock assembly actuator member is in said second position,said interlock assembly latching member is in said second position. 10.The interlock assembly of claim 7 wherein when said power connectorfirst housing and said power connector second housing are in said secondconfiguration, and, when said interlock assembly locking member is insaid second position, said interlock assembly locking member is disposedin an obstructing position relative to said interlock assembly actuatormember.
 11. The interlock assembly of claim 7 wherein when said powerconnector first housing and said power connector second housing are infirst configuration, and, said interlock assembly locking member is insaid second position, said interlock assembly locking member is in anobstructing position relative to said interlock assembly actuatormember.
 12. The interlock assembly of claim 7 wherein: said interlockassembly locking member including a first locking surface and a secondlocking surface; said interlock assembly locking member movably coupledto said first housing, said interlock assembly locking member movablebetween a first position wherein said interlock assembly locking memberfirst locking surface is in a first position and said interlock assemblylocking member second locking surface is in a first position, and asecond position wherein said interlock assembly locking member firstlocking surface is in a second position and said interlock assemblylocking member second locking surface is in a second position; aninterlock assembly latching member assembly, said interlock assemblylatching member assembly including an interlock assembly latchingmember; said interlock assembly latching member including a firstlatching surface; said interlock assembly latching member movablycoupled to said first housing, said interlock assembly latching membermovable between a first position, wherein said interlock assemblylatching member first latching surface is in a first position, and asecond position, wherein said interlock assembly latching member firstlatching surface is in a second position; an interlock assembly actuatormember, said interlock assembly actuator member coupled to said secondhousing, said interlock assembly actuator member including a secondlatching surface; said interlock assembly actuator member movablebetween a first position, wherein said interlock assembly actuatormember is spaced from said interlock assembly latching member, and asecond position, wherein said interlock assembly actuator memberoperatively engages said interlock assembly latching member; saidinterlock assembly actuator member first position corresponding to saidpower connector first housing and said power connector second housingfirst configuration, and, said interlock assembly actuator member secondposition corresponding to said power connector first housing and saidpower connector second housing second configuration; wherein, when saidinterlock assembly actuator member is in said first position, saidinterlock assembly latching member is in said first position, and saidinterlock assembly locking member is in said first position; wherein,when said interlock assembly latching member is in said first positionsaid interlock assembly latching member first latching surface isdisposed in an obstructing position relative to said interlock assemblylocking member first locking surface, wherein said interlock assemblylocking member is maintained in said first position; wherein, when saidinterlock assembly locking member is in said first position, saidinterlock assembly locking member second locking surface is not in anobstructing position relative to said interlock assembly actuatormember; wherein, when said interlock assembly latching member is in saidsecond position, said interlock assembly latching member first latchingsurface is not disposed in an obstructing position relative to saidinterlock assembly locking member first locking surface, wherein saidinterlock assembly locking member is movable to said second position;and wherein, when said interlock assembly locking member is in saidsecond position, said interlock assembly locking member second lockingsurface is in an obstructing position relative to said interlockassembly actuator member second latching surface, wherein said interlockassembly actuator member is maintained in said second position.
 13. Theinterlock assembly of claim 12 wherein said power connector firsthousing and said power connector second housing further move between afirst transition configuration, wherein said power connector firsthousing and said power connector second housing move from said firstconfiguration to said second configuration, and a second transitionconfiguration, wherein said power connector first housing and said powerconnector second housing move from said second configuration to saidfirst configuration, and wherein: said interlock assembly actuatormember further moves between a first transition position, wherein saidinterlock assembly actuator member moves from its first position to itssecond position and wherein said interlock assembly actuator memberoperatively engages said interlock assembly latching member and movessaid interlock assembly latching member from its first position to itssecond position, and, a second transition position, wherein saidinterlock assembly actuator member moves from its second position to itsfirst position and wherein said interlock assembly actuator memberdisengages said interlock assembly latching member and moves saidinterlock assembly latching member from its second position to its firstposition; and wherein said interlock assembly actuator member firsttransition position corresponds to said power connector first housingand said power connector second housing first transition configuration,and, said interlock assembly actuator member second transition positioncorresponds to said power connector first housing and said powerconnector second housing second transition configuration.
 14. Theinterlock assembly of claim 7 wherein: said interlock assembly latchingmember including a body with a base member, an angled engagement surfaceand a number of protrusions; said interlock assembly latching memberfirst latching surface disposed on said interlock assembly latchingmember body number of protrusions; said interlock assembly lockingmember including a body defining a number of cavities; and an interlockassembly locking member first locking surface disposed on said interlockassembly locking member body number of cavities.
 15. The interlockassembly of claim 7 wherein said interlock assembly actuator member isunitary with said second housing.
 16. The interlock assembly of claim 7wherein said second housing is a generally circular housing and wherein:said interlock assembly actuator member is unitary with said secondhousing; said interlock assembly actuator member protrudes generallyradially from said second housing; and said interlock assembly actuatormember second latching surface is a generally axial surface relative tosaid second housing.